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Working Papers in Health Policy and Management
Volume 3
Department of Health Care Management
Andrew Street, David Scheller
Alexander Geissler and Reinhard Busse
Determinants of hospital costs
and performance variation
Methods, models and variables
for the EuroDRG project
Working Papers in Health Policy and Management
Department of Health Care Management
Andrew Street, David Scheller-Kreinsen,
Reinhard Busse
Determinants of hospital costs
and performance variation:
Methods, models and variables
EuroDRG project
May 2010
Determinants of hospital costs
:
Determinants of hospital costs and performance variation
Working Papers in Health Policy and Management
Andrew Street,1 David Scheller
Determinants of hospital co
variables for the EuroDRG project
Working Papers in Health Policy and Management
Volume 3
May 2010
1 Andrew Street is a professor of Health Economics and
in the Centre for Health Economics
2 David Scheller-Kreinsen and Alexander Geissler
of Health Care Management at the
3 Reinhard Busse is a professor and head
at the Berlin University of Technology
EDITOR-IN-CHIEF / HERAUSGEBER DER
Prof. Dr. med. Reinhard Busse
EDITOR / REDAKTEUR
Matthew Gaskins
PUBLISHER AND DISTRIBUTOR / V
Universitätsverlag der Technischen Universität Berlin
Universitätsbibliothek
Fasanenstr. 88 (im VOLKSWAGEN
Tel.: +49 30 314 76131; Fax.:
e-mail: [email protected]
http://www.univerlag.tu-berlin.de/
ISBN 978-3-7983-2124-3
© FG Management im Gesundheitswesen, Technische Universität Berlin
Dieses Werk ist urheberrechtlich geschützt. Die dadurch begründeten Rechte, insbesondere die der Übersetzung, des
Nachdrucks, des Vortrags, der Entnahme von Abbildungen und Tabellen, der Funksendung, der Mikroverfilmung oder
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Einzelfall nur in den Grenzen der gesetzlichen Bestimmungen
Deutschland vom 9. September 1965 in der jeweils geltenden Fassung zulässig. Sie ist grundsätzlich vergütungspflichtig.
Zuwiderhandlungen unterliegen den Strafbestimmungen des Urheberrechtsgesetzes.
eterminants of hospital costs and performance variation
Working Papers in Health Policy and Management, Vol. 3/2010
David Scheller-Kreinsen,2 Alexander Geissler2 and Reinhard Busse
eterminants of hospital costs and performance variation: Methods, models and
for the EuroDRG project
Working Papers in Health Policy and Management
rofessor of Health Economics and director of the Health Policy team
in the Centre for Health Economics (CHE) at the University of York, UK.
Kreinsen and Alexander Geissler are research fellows in
Care Management at the Berlin University of Technology, Germany.
rofessor and head of the Department of Health Care Management
Berlin University of Technology, Germany.
ERAUSGEBER DER SCHRIFTENREIHE
Prof. Dr. med. Reinhard Busse
VERLAG UND VERTRIEB
Universitätsverlag der Technischen Universität Berlin
Fasanenstr. 88 (im VOLKSWAGEN-Haus), D-10623 Berlin
76131; Fax.: +49 30 314 76133
ail: [email protected]
berlin.de/
© FG Management im Gesundheitswesen, Technische Universität Berlin
Dieses Werk ist urheberrechtlich geschützt. Die dadurch begründeten Rechte, insbesondere die der Übersetzung, des
Nachdrucks, des Vortrags, der Entnahme von Abbildungen und Tabellen, der Funksendung, der Mikroverfilmung oder
n Wegen und der Speicherung in Datenverarbeitungsanlagen, bleiben, auch bei nur
auszugsweiser Verwertung, vorbehalten. Eine Vervielfältigung dieses Werkes oder von Teilen dieses Werkes ist auch im
Einzelfall nur in den Grenzen der gesetzlichen Bestimmungen des Urheberrechtsgesetzes der Bundesrepublik
Deutschland vom 9. September 1965 in der jeweils geltenden Fassung zulässig. Sie ist grundsätzlich vergütungspflichtig.
Zuwiderhandlungen unterliegen den Strafbestimmungen des Urheberrechtsgesetzes.
I
Reinhard Busse3
ethods, models and
irector of the Health Policy team
llows in the Department
, Germany.
of the Department of Health Care Management
Dieses Werk ist urheberrechtlich geschützt. Die dadurch begründeten Rechte, insbesondere die der Übersetzung, des
Nachdrucks, des Vortrags, der Entnahme von Abbildungen und Tabellen, der Funksendung, der Mikroverfilmung oder
n Wegen und der Speicherung in Datenverarbeitungsanlagen, bleiben, auch bei nur
auszugsweiser Verwertung, vorbehalten. Eine Vervielfältigung dieses Werkes oder von Teilen dieses Werkes ist auch im
des Urheberrechtsgesetzes der Bundesrepublik
Deutschland vom 9. September 1965 in der jeweils geltenden Fassung zulässig. Sie ist grundsätzlich vergütungspflichtig.
Determinants of hospital costs and performance variation
Working Papers in Health Policy and Management
The EuroDRG project
Payment mechanisms represent one of the fundamental building blocks of any health
system, introducing powerful incentives for actors in the system and
design challenges. Inpatient case p
groups (DRGs), are used nowadays
seek to reimburse providers fairly for the work they undertake. Moreover, they intend to
encourage efficient delivery and to discourage the provision of unnecessary
Thereby are thought to overcome some of the drawbacks of more traditional hospital
reimbursement systems. A case payment system that fulfils these hopes requires
carefully balanced incentives as well as a methodologically sound system. Especially
DRGs need to accurately reflect the resources and costs of treating a given patient.
Fierce debate among practitioners, researchers and the public indicates that case
payments still pose considerable technical and policy challenges, and many unresolved
issues in their implementation remain. For example the HealthBASKET, project showed
that DRG systems differ greatly between European Member States. One of the key
conclusions of HealthBASKET was that structural components may play an even more
important role than heterogeneity of treatment patters in cost variations within an
episode of care. In this context, many European DRG systems may be heading in the
wrong direction by concentrating almost exclusively on refining the medical classification
of DRGs. In addition, over the last decade the Europeanization of health service markets
generated pressure on national reimbursement systems. Increasing patient mobility
caused growing health system interconnectedness. The EuroDRG project scrutin
challenges. Part one concentrates on the complexities of case payments for hospitals in
national contexts. Special emphasis is put on identifying those factors, which are crucial
for (1) calculating adequate case payments, (2) examining hospital efficiency within
countries and across Europe fairly and (3) studying the relationship between costs and
the quality of care provided in hospitals. The project uses comparative analyses of DRG
systems across 10 European countries embedded in various types of health systems
(Austria, Estonia, Finland, France, Germany, the Netherlands, Poland, Spain, Sweden,
Ireland, UK). The second part of the project seeks to identify pan
hospital case payment by conducting cost analysis across European countries.
Furthermore, the systemic factors, which are crucial for successful policy design in a
slowly emerging pan-European hospital market, will be identified. Special emphasis is
placed on (1) identifying ways to calculate these payments in an adequate fashion, (2)
examining hospital efficiency within and across European countries, and (3) identifying
factors that affect the relationship between the costs
Acknowledgements
The review presented in this working paper
“EuroDRG – Diagnosis-related groups in Europe: towards efficiency and quality
(www.eurodrg.eu), which is funded by the European
Framework Programme.
eterminants of hospital costs and performance variation
Working Papers in Health Policy and Management, Vol. 3/2010
project
Payment mechanisms represent one of the fundamental building blocks of any health
system, introducing powerful incentives for actors in the system and important
. Inpatient case payments, mainly referred to as diagnosis
nowadays as a payment mechanism with ambitious aims: they
seek to reimburse providers fairly for the work they undertake. Moreover, they intend to
encourage efficient delivery and to discourage the provision of unnecessary
Thereby are thought to overcome some of the drawbacks of more traditional hospital
reimbursement systems. A case payment system that fulfils these hopes requires
carefully balanced incentives as well as a methodologically sound system. Especially
DRGs need to accurately reflect the resources and costs of treating a given patient.
Fierce debate among practitioners, researchers and the public indicates that case
payments still pose considerable technical and policy challenges, and many unresolved
ssues in their implementation remain. For example the HealthBASKET, project showed
that DRG systems differ greatly between European Member States. One of the key
conclusions of HealthBASKET was that structural components may play an even more
e than heterogeneity of treatment patters in cost variations within an
episode of care. In this context, many European DRG systems may be heading in the
wrong direction by concentrating almost exclusively on refining the medical classification
addition, over the last decade the Europeanization of health service markets
generated pressure on national reimbursement systems. Increasing patient mobility
caused growing health system interconnectedness. The EuroDRG project scrutin
. Part one concentrates on the complexities of case payments for hospitals in
national contexts. Special emphasis is put on identifying those factors, which are crucial
for (1) calculating adequate case payments, (2) examining hospital efficiency within
untries and across Europe fairly and (3) studying the relationship between costs and
the quality of care provided in hospitals. The project uses comparative analyses of DRG
systems across 10 European countries embedded in various types of health systems
ustria, Estonia, Finland, France, Germany, the Netherlands, Poland, Spain, Sweden,
Ireland, UK). The second part of the project seeks to identify pan-European issues in
hospital case payment by conducting cost analysis across European countries.
e, the systemic factors, which are crucial for successful policy design in a
European hospital market, will be identified. Special emphasis is
placed on (1) identifying ways to calculate these payments in an adequate fashion, (2)
ing hospital efficiency within and across European countries, and (3) identifying
factors that affect the relationship between the costs and quality of inpatient care.
Acknowledgements
presented in this working paper was generated in the conte
related groups in Europe: towards efficiency and quality
which is funded by the European Commission under t
II
Payment mechanisms represent one of the fundamental building blocks of any health
important technical
ayments, mainly referred to as diagnosis-related
as a payment mechanism with ambitious aims: they
seek to reimburse providers fairly for the work they undertake. Moreover, they intend to
encourage efficient delivery and to discourage the provision of unnecessary services.
Thereby are thought to overcome some of the drawbacks of more traditional hospital
reimbursement systems. A case payment system that fulfils these hopes requires
carefully balanced incentives as well as a methodologically sound system. Especially,
DRGs need to accurately reflect the resources and costs of treating a given patient.
Fierce debate among practitioners, researchers and the public indicates that case
payments still pose considerable technical and policy challenges, and many unresolved
ssues in their implementation remain. For example the HealthBASKET, project showed
that DRG systems differ greatly between European Member States. One of the key
conclusions of HealthBASKET was that structural components may play an even more
e than heterogeneity of treatment patters in cost variations within an
episode of care. In this context, many European DRG systems may be heading in the
wrong direction by concentrating almost exclusively on refining the medical classification
addition, over the last decade the Europeanization of health service markets
generated pressure on national reimbursement systems. Increasing patient mobility
caused growing health system interconnectedness. The EuroDRG project scrutinizes these
. Part one concentrates on the complexities of case payments for hospitals in
national contexts. Special emphasis is put on identifying those factors, which are crucial
for (1) calculating adequate case payments, (2) examining hospital efficiency within
untries and across Europe fairly and (3) studying the relationship between costs and
the quality of care provided in hospitals. The project uses comparative analyses of DRG
systems across 10 European countries embedded in various types of health systems
ustria, Estonia, Finland, France, Germany, the Netherlands, Poland, Spain, Sweden,
European issues in
hospital case payment by conducting cost analysis across European countries.
e, the systemic factors, which are crucial for successful policy design in a
European hospital market, will be identified. Special emphasis is
placed on (1) identifying ways to calculate these payments in an adequate fashion, (2)
ing hospital efficiency within and across European countries, and (3) identifying
and quality of inpatient care.
was generated in the context of the project
related groups in Europe: towards efficiency and quality”
under the Seventh
Determinants of hospital costs and performance variation
Working Papers in Health Policy and Management
Contents
1 Introduction................................
2 Conceptual and methodological framework
2.1 Analysis of patient-level costs
2.2 Analysis of patient-level length of stay
2.3 Analysis of hospital-
3 Explanatory factors
3.1 Patient-level variables
3.2 Hospital characteristics
3.2.1 Teaching status ................................
3.2.2 Ownership ................................
3.2.3 Volume of activity: economies of scale
3.2.4 Range of activity: specialization versus economies of scope
3.2.5 Quality ................................
3.2.6 Technological equipment
3.2.7 Geographical variation in input costs
3.2.8 Geographical location
Appendix ................................
1 Examining hospital performance
2 Specification choices
2.1 Transformation of variables
2.2 Total vs. average cost function
2.3 Functional form ................................
2.4 Input variables ................................
2.5 Outputs ................................
2.6 Environmental variables
2.7 Weights ................................
2.8 Dynamic nature of production
2.9 Modelling the error term
2.10 One versus two stage estimation
3 Efficiency analysis ................................
3.1 The main approaches to efficiency analysis: SFA and DEA
3.2 Comparing DEA and SFA
References ................................
eterminants of hospital costs and performance variation
Working Papers in Health Policy and Management, Vol. 3/2010
................................................................................................
Conceptual and methodological framework ................................
level costs ................................................................
level length of stay ................................................................
-level costs ................................................................
Explanatory factors ............................................................................................
level variables ................................................................................................
Hospital characteristics ............................................................................................
................................................................................................
................................................................................................
activity: economies of scale................................................................
Range of activity: specialization versus economies of scope ................................
................................................................................................
l equipment ................................................................
Geographical variation in input costs ................................................................
Geographical location ..............................................................................................
................................................................................................
Examining hospital performance – the nature of the problem ..........................
Specification choices ................................................................
Transformation of variables ................................................................
Total vs. average cost function ................................................................
................................................................................................
................................................................................................
................................................................................................
riables ...........................................................................................
................................................................................................
Dynamic nature of production ................................................................
Modelling the error term ................................................................
One versus two stage estimation ................................................................
............................................................................................
The main approaches to efficiency analysis: SFA and DEA ................................
Comparing DEA and SFA...........................................................................................
................................................................................................
III
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....................................................... 4
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................................................... 7
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Determinants of hospital costs and performance variation
1 Introduction
The use of case payments intends to provide incentives for cost containment,
efficiency and – at least in its theoretical formulation
1985). Although diagnosis
countries, hospital costs do not
variations in hospital cost structures persist
observation, various theoretical considerations
extend the scope of DRG systems to private sections of the hosp
in England or in France, have
for specific health care services can be applied across hospitals.
Instead, researchers are increasingly recognizing
can be due to differences in the following categories of explanatory variables:
(1) patient mix (e.g. age, gender, socio
(2) diagnostics and treatment (both regarding the
technologies as well as the inten
“hospital/medical decision variables”),
(3) costs per unit of staff or technology (determined either by the hospital managers
or being beyond their control
(4) the factors that are incl
variations in costs would then be explained through the way costs are calculated,
and what might be structurally left out).
The new paradigm in academ
al. 2008b), which takes cost variation due to factors beyond the control of hospital
managers into account. The underlying rationale is that the funding formula has to
take account of “legitimate
structural variables) in order to avoid incentivizing unintended consequences in the
hospital sector such as patient selection, lower quality of care, creaming, skimping
and dumping (Dormont and Milcent 2004)
eterminants of hospital costs and performance variation
The use of case payments intends to provide incentives for cost containment,
at least in its theoretical formulation – to reward quality
diagnosis-related groups (DRGs) have been used for years
countries, hospital costs do not appear to have converged; indeed,
variations in hospital cost structures persist (Busse et al. 2008b). This empirical
observation, various theoretical considerations, and recent policy initiatives to
extend the scope of DRG systems to private sections of the hospital market
have led many to rethink the idea that a uniform payment
for specific health care services can be applied across hospitals.
are increasingly recognizing that differences in costs per DRG
an be due to differences in the following categories of explanatory variables:
patient mix (e.g. age, gender, socio-economic status, severity),
(2) diagnostics and treatment (both regarding the use/mix of new and emerging
technologies as well as the intensity, e.g. physician or nursing time
“hospital/medical decision variables”),
(3) costs per unit of staff or technology (determined either by the hospital managers
or being beyond their control – “structural variables”) and
(4) the factors that are included in the costs calculations (hence, the observed
variations in costs would then be explained through the way costs are calculated,
and what might be structurally left out).
The new paradigm in academia is therefore to establish a fair playing field
, which takes cost variation due to factors beyond the control of hospital
managers into account. The underlying rationale is that the funding formula has to
legitimate” cost heterogeneity (due to patient, treatment or
tural variables) in order to avoid incentivizing unintended consequences in the
hospital sector such as patient selection, lower quality of care, creaming, skimping
(Dormont and Milcent 2004).
1
The use of case payments intends to provide incentives for cost containment,
to reward quality (Shleifer
have been used for years in many
d; indeed, rather large
. This empirical
recent policy initiatives to
ital market, such as
led many to rethink the idea that a uniform payment
that differences in costs per DRG
an be due to differences in the following categories of explanatory variables:
mix of new and emerging
sity, e.g. physician or nursing time –
(3) costs per unit of staff or technology (determined either by the hospital managers
uded in the costs calculations (hence, the observed
variations in costs would then be explained through the way costs are calculated,
ia is therefore to establish a fair playing field (Mason et
, which takes cost variation due to factors beyond the control of hospital
managers into account. The underlying rationale is that the funding formula has to
cost heterogeneity (due to patient, treatment or
tural variables) in order to avoid incentivizing unintended consequences in the
hospital sector such as patient selection, lower quality of care, creaming, skimping
Determinants of hospital costs and performance variation
The purpose of this review is to examine the international evidence for existing
instruments, systems or concepts for measuring and explaining differences in
hospital costs. Costs here are defined as costs to the hospital to produce services
rather than cost to purchasers (“pric
hospital.
The intention is to review
“hospital/medical decision variables”. The key question is to assess t
(in)adequacyof existing DRG
identify the structural or regional criteria that might need to be considered in
analyzing hospital costs.
The review can be divided into two parts. The first will inform the analytical models
applied in the analysis of p
of stay (as a proxy for cost) of the EuroDRG project. The objectives of these two
approaches are the same, namely:
• To calculate costs (or length of stay) per case for each defined episode of care
per country;
• To estimate cost (or length of stay) functions for each episode of care and
joint functions including all care episodes utilizing the full set of explanatory
variables across countries;
• To explore which adjustment factors explain variation in
length of stay) per country;
• To elaborate how far the DRG
empirically analysed variation in costs (or length of stay) into account, and
adequately capturing the
Empirical studies of variation in hospital costs fall into two camps: those based on
analysis of the costs of individual patients and those
analyse costs reported at hospital level. In this review, we consider how patient
and hospital-level data are related and outline the approaches to analyzing these
data. The second part of the review
appears in the appendix to maintain a short and concise core text. This part of the
eterminants of hospital costs and performance variation
iew is to examine the international evidence for existing
instruments, systems or concepts for measuring and explaining differences in
hospital costs. Costs here are defined as costs to the hospital to produce services
rather than cost to purchasers (“price”), which is revenue from the point of the
The intention is to review but go beyond consideration of patient case
“hospital/medical decision variables”. The key question is to assess t
of existing DRG systems with regard to their (risk-)adjustment and to
identify the structural or regional criteria that might need to be considered in
The review can be divided into two parts. The first will inform the analytical models
applied in the analysis of patient-level cost data and in analyzing patient
of stay (as a proxy for cost) of the EuroDRG project. The objectives of these two
approaches are the same, namely:
To calculate costs (or length of stay) per case for each defined episode of care
To estimate cost (or length of stay) functions for each episode of care and
joint functions including all care episodes utilizing the full set of explanatory
variables across countries;
To explore which adjustment factors explain variation in hospital costs (or
length of stay) per country;
To elaborate how far the DRG classification of each country is taking this
empirically analysed variation in costs (or length of stay) into account, and
adequately capturing the “legitimate” heterogeneity.
Empirical studies of variation in hospital costs fall into two camps: those based on
analysis of the costs of individual patients and those – the vast majority
analyse costs reported at hospital level. In this review, we consider how patient
level data are related and outline the approaches to analyzing these
data. The second part of the review, which concentrates on hospital
appears in the appendix to maintain a short and concise core text. This part of the
2
iew is to examine the international evidence for existing
instruments, systems or concepts for measuring and explaining differences in
hospital costs. Costs here are defined as costs to the hospital to produce services
e”), which is revenue from the point of the
but go beyond consideration of patient case-mix and
“hospital/medical decision variables”. The key question is to assess the
)adjustment and to
identify the structural or regional criteria that might need to be considered in
The review can be divided into two parts. The first will inform the analytical models
level cost data and in analyzing patient-level length
of stay (as a proxy for cost) of the EuroDRG project. The objectives of these two
To calculate costs (or length of stay) per case for each defined episode of care
To estimate cost (or length of stay) functions for each episode of care and
joint functions including all care episodes utilizing the full set of explanatory
hospital costs (or
classification of each country is taking this
empirically analysed variation in costs (or length of stay) into account, and
Empirical studies of variation in hospital costs fall into two camps: those based on
the vast majority – that
analyse costs reported at hospital level. In this review, we consider how patient-level
level data are related and outline the approaches to analyzing these
which concentrates on hospital-level analysis,
appears in the appendix to maintain a short and concise core text. This part of the
Determinants of hospital costs and performance variation
review considers general specification choices as well as methods of efficiency
analysis.
Define ik
c as the cost of treating patient
straightforward to add together
to arrive at the hospital’s total cost:
1
I
k ik
i
TC c=
=∑
For those countries for which individual patient cost data are available, an analysis of
variation in individual patient costs
formulate models of patient costs in section 2.1.
In some countries, patient
used as a proxy for costs, at least for those episodes of care that are delivered in the
inpatient setting. The fact that the distributions of cost and length of stay differ
means that we have to adopt slightly different estimation procedures, and these are
outlined in section 2.2.
For completeness, in section 2.3 we also indicate how patient
are related to hospital-level cost functions typically analysed in the
literature.
The primary question of interest is: why do hospital costs or lengths of stay vary
among patients? Broadly speaking, costs or lengths of stay vary for two reasons:
• Firstly because patients have very different characteristics or are d
and treated differently (the first two sets of variables named above)
• Secondly because of the characteristics of the hospital where their treatment
is delivered (both within and beyond the control of hospital managers).
The research in the EuroDRG
these reasons. We discuss the type of patient characteristics and hospital
characteristics that should be accounted for in section 3.
eterminants of hospital costs and performance variation
considers general specification choices as well as methods of efficiency
as the cost of treating patient , 1...i i I= , in hospital , 1...k k K
straightforward to add together the costs for each individual patient in each hospital
to arrive at the hospital’s total cost:
For those countries for which individual patient cost data are available, an analysis of
variation in individual patient costs ikc will be undertaken. We consider how to
formulate models of patient costs in section 2.1.
patient-level cost data are unavailable, but length of stay can be
used as a proxy for costs, at least for those episodes of care that are delivered in the
inpatient setting. The fact that the distributions of cost and length of stay differ
at we have to adopt slightly different estimation procedures, and these are
For completeness, in section 2.3 we also indicate how patient-level cost functions
level cost functions typically analysed in the
The primary question of interest is: why do hospital costs or lengths of stay vary
among patients? Broadly speaking, costs or lengths of stay vary for two reasons:
Firstly because patients have very different characteristics or are d
and treated differently (the first two sets of variables named above)
Secondly because of the characteristics of the hospital where their treatment
is delivered (both within and beyond the control of hospital managers).
The research in the EuroDRG project is designed in a way to identify and disentangle
these reasons. We discuss the type of patient characteristics and hospital
characteristics that should be accounted for in section 3.
3
considers general specification choices as well as methods of efficiency
, 1...k k K= . It is
the costs for each individual patient in each hospital
(1)
For those countries for which individual patient cost data are available, an analysis of
will be undertaken. We consider how to
but length of stay can be
used as a proxy for costs, at least for those episodes of care that are delivered in the
inpatient setting. The fact that the distributions of cost and length of stay differ
at we have to adopt slightly different estimation procedures, and these are
level cost functions
level cost functions typically analysed in the empirical
The primary question of interest is: why do hospital costs or lengths of stay vary
among patients? Broadly speaking, costs or lengths of stay vary for two reasons:
Firstly because patients have very different characteristics or are diagnosed
and treated differently (the first two sets of variables named above)
Secondly because of the characteristics of the hospital where their treatment
is delivered (both within and beyond the control of hospital managers).
project is designed in a way to identify and disentangle
these reasons. We discuss the type of patient characteristics and hospital
Determinants of hospital costs and performance variation
2 Conceptual and methodological framework
2.1 Analysis of patient
If patient-level cost data are available, analysis of why costs differ among patients
can be undertaken by specifying a hierarchical or multi
recognizes that patients (level 1) are clustered within hospitals (level 2). The
might take the following general form:
1
N
ik n ik k ik
n
c α β ω ε=
= + + +∑ x
Where ikc is the cost of patient
describe patient i in hospital
(diagnosis, severity, co-morbidities) and socio
economic status etc.) characteristics as well as “hospital
i.e. diagnostics and treatment. These variables
section 3.1. kω captures the hospital influence on costs over and above the patient
characteristics while ikε is the standard disturbance.
Typically the distribution of
having much higher costs than the majority. So as to avoid these high cost patients
exerted undue influence on the estimated relationships, we convert costs into
logarithmic form, which serves to norm
Moreover, because there are only two levels to the hierarchy (patients clustered in
hospitals), equation (1) c
effects panel data models. Which model is most app
dataset being analysed can be established by a Hausman test
Whether estimated by applying a fixed or random effects model
“hospital effects” and can be interpreted as a measure of hospital performance,
higher values implying that this hospital’s costs are above average after taking into
account the characteristics of the patients being treated
choice and intensity of the diagnostics and treatment itself. These estimates (
can themselves be analysed to explore reasons why some hospitals appear to have
eterminants of hospital costs and performance variation
Conceptual and methodological framework
Analysis of patient-level costs
level cost data are available, analysis of why costs differ among patients
can be undertaken by specifying a hierarchical or multi-level model, which
s that patients (level 1) are clustered within hospitals (level 2). The
might take the following general form:
ik n ik k ikα β ω ε
is the cost of patient i in hospital k, ikx is a vector of n
in hospital k, regarding their “patient variables”, i.e. medical
morbidities) and socio-demographic (age, gender, socio
economic status etc.) characteristics as well as “hospital/medical decision variables”,
i.e. diagnostics and treatment. These variables will be described at greater length in
captures the hospital influence on costs over and above the patient
is the standard disturbance.
Typically the distribution of patient costs is positively skewed, with some patients
having much higher costs than the majority. So as to avoid these high cost patients
exerted undue influence on the estimated relationships, we convert costs into
logarithmic form, which serves to normalize the overall distribution of costs.
Moreover, because there are only two levels to the hierarchy (patients clustered in
hospitals), equation (1) can be estimated using standard fixed effects or random
panel data models. Which model is most appropriate for the particular
dataset being analysed can be established by a Hausman test (1978).
mated by applying a fixed or random effects model ω
and can be interpreted as a measure of hospital performance,
higher values implying that this hospital’s costs are above average after taking into
count the characteristics of the patients being treated (Hauck et al.
choice and intensity of the diagnostics and treatment itself. These estimates (
can themselves be analysed to explore reasons why some hospitals appear to have
4
level cost data are available, analysis of why costs differ among patients
level model, which
s that patients (level 1) are clustered within hospitals (level 2). The model
(2)
n variables that
their “patient variables”, i.e. medical
demographic (age, gender, socio-
medical decision variables”,
will be described at greater length in
captures the hospital influence on costs over and above the patient
patient costs is positively skewed, with some patients
having much higher costs than the majority. So as to avoid these high cost patients
exerted undue influence on the estimated relationships, we convert costs into
the overall distribution of costs.
Moreover, because there are only two levels to the hierarchy (patients clustered in
an be estimated using standard fixed effects or random
ropriate for the particular
kω are termed
and can be interpreted as a measure of hospital performance,
higher values implying that this hospital’s costs are above average after taking into
(Hauck et al. 2003) and the
choice and intensity of the diagnostics and treatment itself. These estimates ( ˆkω )
can themselves be analysed to explore reasons why some hospitals appear to have
Determinants of hospital costs and performance variation
higher costs than others. For instance, costs may vary according to the volume of
activity if there are economies
specialist hospitals. We shall consider these characteristics in section 3.2 but, for the
moment, we summarize
characteristics (both under and beyond the control of hospital managers).
One way to account for hospital characteristics is to adopt a single
using a model developed by Battese and Coelli
form:
1 1
N M
ik n ik k m k k ik
n m
c α β ω γ µ ε= =
= + + + +
∑ ∑x z
It is not always feasible to estimate this model, particularly the fixed effects
specification is employed and some hospitals have unique characteristics. This makes
it impossible to distinguish the influence of the characteristic from the hospital fixed
effect.
An alternative is to specify an Estimated Dependent Variable model, as used in
Laudicella et al. (2009), where
1
ˆM
k o m k k
m
ω α γ µ=
= + +∑ z
This model forms the standard approach in the EuroDRGs project. For certain
countries the Battese & Coelli approach may also be explored.
A major advantage of using patient
legal entity (e.g. hospital) as the unit of analysis. Instead, data can be clustered to
whatever level is deemed appropriate to the
patient-level data enables consideration of specific
likely to be greater standard
undertaken. For instance, Laudicella et al.
obstetrics departments and Kristensen et al.
for patients admitted
HealthBASKET, used so-called vignettes, which in effect were patients with well
eterminants of hospital costs and performance variation
higher costs than others. For instance, costs may vary according to the volume of
activity if there are economies of scale or may be different in, say,
hospitals. We shall consider these characteristics in section 3.2 but, for the
them as a vector kmz of m variables measuring hospital
characteristics (both under and beyond the control of hospital managers).
way to account for hospital characteristics is to adopt a single
using a model developed by Battese and Coelli (1995). This might take the following
1 1
ik n ik k m k k ikα β ω γ µ ε= =
= + + + +
∑ ∑x z
It is not always feasible to estimate this model, particularly the fixed effects
specification is employed and some hospitals have unique characteristics. This makes
it impossible to distinguish the influence of the characteristic from the hospital fixed
An alternative is to specify an Estimated Dependent Variable model, as used in
, where ˆkω is regressed against the hospital characteristics:
This model forms the standard approach in the EuroDRGs project. For certain
Coelli approach may also be explored.
A major advantage of using patient-level data is that it is not necessary to use the
hospital) as the unit of analysis. Instead, data can be clustered to
whatever level is deemed appropriate to the question. Most importantly, the use of
bles consideration of specific production lines, where there is
likely to be greater standardization in the types of patients treated and activities
undertaken. For instance, Laudicella et al. (2009) consider patients clustered within
obstetrics departments and Kristensen et al. (2009) examine costs of hospital care
with diabetes. The predecessor project to EuroDRG,
called vignettes, which in effect were patients with well
5
higher costs than others. For instance, costs may vary according to the volume of
may be different in, say, teaching or
hospitals. We shall consider these characteristics in section 3.2 but, for the
variables measuring hospital
characteristics (both under and beyond the control of hospital managers).
way to account for hospital characteristics is to adopt a single-step process,
. This might take the following
(3)
It is not always feasible to estimate this model, particularly the fixed effects
specification is employed and some hospitals have unique characteristics. This makes
it impossible to distinguish the influence of the characteristic from the hospital fixed
An alternative is to specify an Estimated Dependent Variable model, as used in
is regressed against the hospital characteristics:
(4)
This model forms the standard approach in the EuroDRGs project. For certain
level data is that it is not necessary to use the
hospital) as the unit of analysis. Instead, data can be clustered to
question. Most importantly, the use of
production lines, where there is
tion in the types of patients treated and activities
consider patients clustered within
examine costs of hospital care
with diabetes. The predecessor project to EuroDRG,
called vignettes, which in effect were patients with well-
Determinants of hospital costs and performance variation
defined medical and socio
differences in diagnostics
were analyzed across nine countries
replacement, stroke, acute myocardial infarction (AMI), child delivery,
appendectomy and cataract surgery.
In the EuroDRG project, the intention is to analyse costs for patients classified to the
same episode of care (building on the vignettes approach, but allowing variability in
medical and socio-demographic variables). Define an episode of care as
1...j J= so that there are a total of
means that, instead of estimating equation (1) for
estimated separately for each episode o
1
N
ik n ik k ik
n
c j j Jα β ω ε=
= + + + ∀ =∑ x
This enables a better capture of the relevant diagnostics
type of hip implant, bare
laparoscopic appendectomy, normal delivery vs. C
variables (such as existence of catheter l
care unit) in kω .
2.2 Analysis of patient
For those countries where patient
be analysed as a proxy for cost. The esti
reflect the fact that the distribution of costs differs from that of length of stay. In
essence, length of stay cannot be considered a continuous variable, so the linear
regression model should not be applied. Inste
models that recognize that length of stay tends to take a limited set of quite low
values with many patients having fairly short lengths of stay and relatively few
staying for longer periods. Moreover, for some episodes o
large proportion of patients who do not stay overnight (hence, being recorded as
having a zero length of stay).
eterminants of hospital costs and performance variation
defined medical and socio-demographic characteristics, for whom the influence of
differences in diagnostics/treatment as well as hospital and country characteristics
were analyzed across nine countries (Busse et al. 2008a). Vignettes included hip
replacement, stroke, acute myocardial infarction (AMI), child delivery,
appendectomy and cataract surgery.
In the EuroDRG project, the intention is to analyse costs for patients classified to the
same episode of care (building on the vignettes approach, but allowing variability in
demographic variables). Define an episode of care as
so that there are a total of J episodes of care dealt with in a hospital. This
means that, instead of estimating equation (1) for all patients in each hospital, it is
estimated separately for each episode of care of interest:
, 1...ik n ik k ikc j j Jα β ω ε= + + + ∀ =
This enables a better capture of the relevant diagnostics/treatment variables (e.g.
type of hip implant, bare-metal stent vs. drug-eluting stent in AMI, open vs.
laparoscopic appendectomy, normal delivery vs. C-section) in ikx as well as structural
variables (such as existence of catheter laboratory, stroke unit or neonatal intensive
Analysis of patient-level length of stay
For those countries where patient-level cost data are unavailable, length of stay will
be analysed as a proxy for cost. The estimation procedure needs to be modified to
reflect the fact that the distribution of costs differs from that of length of stay. In
essence, length of stay cannot be considered a continuous variable, so the linear
regression model should not be applied. Instead, it is better to use count data
that length of stay tends to take a limited set of quite low
values with many patients having fairly short lengths of stay and relatively few
staying for longer periods. Moreover, for some episodes of care, there might be a
large proportion of patients who do not stay overnight (hence, being recorded as
having a zero length of stay).
6
demographic characteristics, for whom the influence of
l as hospital and country characteristics
ettes included hip
replacement, stroke, acute myocardial infarction (AMI), child delivery,
In the EuroDRG project, the intention is to analyse costs for patients classified to the
same episode of care (building on the vignettes approach, but allowing variability in
demographic variables). Define an episode of care as j , with
episodes of care dealt with in a hospital. This
patients in each hospital, it is
(5)
treatment variables (e.g.
eluting stent in AMI, open vs.
as well as structural
aboratory, stroke unit or neonatal intensive
level cost data are unavailable, length of stay will
mation procedure needs to be modified to
reflect the fact that the distribution of costs differs from that of length of stay. In
essence, length of stay cannot be considered a continuous variable, so the linear
ad, it is better to use count data
that length of stay tends to take a limited set of quite low
values with many patients having fairly short lengths of stay and relatively few
f care, there might be a
large proportion of patients who do not stay overnight (hence, being recorded as
Determinants of hospital costs and performance variation
The main count data models are the Poisson regression model and the negative
binomial regression model, with the latt
length-of-stay data that we will be examining. For episodes of care with a high
proportion of zero values, the zero
appropriate. Good introductions to count data models
Trivedi (1986), Long (1997)
2.3 Analysis of hospital
As mentioned, most empirical studies of hospital costs take the hospital as the unit
of analysis, mainly because data are reported at this level of aggregation. This is
problematic, however, because a common production function cannot be assumed.
Potentially this renders analysis invalid, because hospitals cannot be considered
comparable.
When only kTC is observed analysis of why some hospitals have different t
than others involves specifying a cost function of the general form:
1 1
N M
k k n k m k k
n m
TC Qα β γ ε= =
= + + + +∑ ∑X z
Where kQ measures the number of patients treated in hospital
should be weighted in order to capture
obvious choice for doing so
ex-ante accepting these weights as appropriate. There are the usual specification
choices associated with estimating this functi
natural units or in logarithmic form, and about the form in which explanatory
variables appear. A review of these specification choices is includ
the Appendix.
Note that it is a simple matter to co
an average cost function simply by dividing total costs by total activity:
1 1
N Mk
k n k m k k
n mk
TCAC
Qα β γ ε
= =
= = + + +∑ ∑X z
eterminants of hospital costs and performance variation
The main count data models are the Poisson regression model and the negative
binomial regression model, with the latter more likely to provide a better fit to the
stay data that we will be examining. For episodes of care with a high
proportion of zero values, the zero-inflated negative binomial model might be
appropriate. Good introductions to count data models are provided by Cameron and
(1997) and Jones (2000).
Analysis of hospital-level costs
As mentioned, most empirical studies of hospital costs take the hospital as the unit
of analysis, mainly because data are reported at this level of aggregation. This is
however, because a common production function cannot be assumed.
Potentially this renders analysis invalid, because hospitals cannot be considered
is observed analysis of why some hospitals have different t
than others involves specifying a cost function of the general form:
1 1
N M
k k n k m k k
n m
α β γ ε= =
= + + + +∑ ∑X z
measures the number of patients treated in hospital k
should be weighted in order to capture differences in (legitimate) costs; the most
obvious choice for doing so – using DRG weights – has, however, the disadvantage of
ante accepting these weights as appropriate. There are the usual specification
choices associated with estimating this function, such as whether to consider costs in
natural units or in logarithmic form, and about the form in which explanatory
variables appear. A review of these specification choices is included as section 2 of
Note that it is a simple matter to convert equation (5) from a total cost function to
an average cost function simply by dividing total costs by total activity:
1 1
N M
k n k m k k
n m
α β γ ε= =
= = + + +∑ ∑X z
7
The main count data models are the Poisson regression model and the negative
er more likely to provide a better fit to the
stay data that we will be examining. For episodes of care with a high
inflated negative binomial model might be
are provided by Cameron and
As mentioned, most empirical studies of hospital costs take the hospital as the unit
of analysis, mainly because data are reported at this level of aggregation. This is
however, because a common production function cannot be assumed.
Potentially this renders analysis invalid, because hospitals cannot be considered
is observed analysis of why some hospitals have different total costs
(6)
k. This number
differences in (legitimate) costs; the most
has, however, the disadvantage of
ante accepting these weights as appropriate. There are the usual specification
on, such as whether to consider costs in
natural units or in logarithmic form, and about the form in which explanatory
ed as section 2 of
nvert equation (5) from a total cost function to
an average cost function simply by dividing total costs by total activity:
(7)
Determinants of hospital costs and performance variation
It is also possible to conduct efficiency analysis of hospital costs, using techniques
such as stochastic frontier or data envelopment analysis
techniques do not materially impact on the specification of the explanatory model,
so we summarize these methods in Appendix 3
In specifications (6 & 7) the vector
equation (1). Although the set of
each individual patient as in
the patients in each hospital. For instance, rather than each patient’s age, age is
specified as some summary (e
evident, therefore, that hospital
about patients than is available in the patient
results are less robust.
Note, however, that the vector of variables
common to the two forms of analysis.
We now consider in more
3 Explanatory factors
3.1 Patient-level variables
The over-riding reason that costs differ among patients is because they suffer from
very different conditions. Diagnosis
patients into mutually exclusive groups of patients, with the patients in each group
having the same expected
clearly depend on both the number of different DRG
defining them and calculating their relative weights). Countries have developed their
own classification systems but, for expositional purposes, define a DRG as
1...j J= . If DRGs capture all the variation in costs that are due to patient
characteristics, it would be possible to analyse variation in the costs of patients in
different hospitals by specifying a simple model of the general form:
'
ik j ik k ikc α ω ε= + + +β D
eterminants of hospital costs and performance variation
It is also possible to conduct efficiency analysis of hospital costs, using techniques
ochastic frontier or data envelopment analysis (Jacobs et al. 2006)
niques do not materially impact on the specification of the explanatory model,
these methods in Appendix 3.
In specifications (6 & 7) the vector kX differs from the vector ikx in the patient
equation (1). Although the set of n variables are similar, rather being measured for
each individual patient as in ikx , each variable in kX is an aggregated summary of
h hospital. For instance, rather than each patient’s age, age is
specified as some summary (e.g. the average) of all patients in the hospital. It is
evident, therefore, that hospital-level analysis makes use of much less information
available in the patient-level analysis. Consequently, the
Note, however, that the vector of variables kmz capturing hospital characteristics is
common to the two forms of analysis.
We now consider in more detail what variables are contained in these vectors.
Explanatory factors
level variables
riding reason that costs differ among patients is because they suffer from
very different conditions. Diagnosis-related groups (DRGs) are designed to classify
patients into mutually exclusive groups of patients, with the patients in each group
having the same expected “legitimate” cost (whether this is actually the case will
clearly depend on both the number of different DRGs used as well as the accuracy of
defining them and calculating their relative weights). Countries have developed their
own classification systems but, for expositional purposes, define a DRG as
If DRGs capture all the variation in costs that are due to patient
characteristics, it would be possible to analyse variation in the costs of patients in
different hospitals by specifying a simple model of the general form:
8
It is also possible to conduct efficiency analysis of hospital costs, using techniques
(Jacobs et al. 2006). These
niques do not materially impact on the specification of the explanatory model,
in the patient-level
variables are similar, rather being measured for
is an aggregated summary of
h hospital. For instance, rather than each patient’s age, age is
the average) of all patients in the hospital. It is
level analysis makes use of much less information
level analysis. Consequently, the
capturing hospital characteristics is
detail what variables are contained in these vectors.
riding reason that costs differ among patients is because they suffer from
roups (DRGs) are designed to classify
patients into mutually exclusive groups of patients, with the patients in each group
cost (whether this is actually the case will
s used as well as the accuracy of
defining them and calculating their relative weights). Countries have developed their
own classification systems but, for expositional purposes, define a DRG as j , with
If DRGs capture all the variation in costs that are due to patient
characteristics, it would be possible to analyse variation in the costs of patients in
(8)
Determinants of hospital costs and performance variation
Where ikD is a vector of dummy variables specifying the DRG to which the patient is
allocated, ku is variation in cost that is attributable to the hospital in which the
patient is treated and ikε
DRGs, though, cannot account for all variation in costs among patients
other characteristics of patients other than their DRG and the hospital where they
are treated that explain their costs.
Some of these characteristics will be of general relevance, such as the patient’s age,
gender or socio-economic status. Hvenegaard et al.
explanatory power, over an
explaining variation in the costs of patients undergoing vascular surgery. In this
study, such variables prove to add little additional information. This is consistent
with the health insurance literature,
individual risk of incurring health expenditure.
Other patient characteristics are more important, and are likely to vary according to
the condition under consideration. For example Hvenegaard et al.
set of characteristics relevant to vascular patients including their sm
diabetes, and ASA score.
The HealthBASKET project has explored in depth the relevance of diagnostics and
treatment (on the patient level) as well as certain structural variables: For hip
replacement, the choice of cemented vs. non
number of hospital beds were significant explanatory factors
stroke, receiving thrombolysis and length of
variables (Epstein et al. 2008)
use of PTCA and stenting, length
hospital (Tiemann 2008). For normal child delivery, the variables length
labour costs for nurses/
appendectomy, open surgery
significantly lower costs,
costs (Schreyögg 2008). For cataract surgery, the
intervention had the highest explanatory power
eterminants of hospital costs and performance variation
is a vector of dummy variables specifying the DRG to which the patient is
is variation in cost that is attributable to the hospital in which the
captures random variation in patient costs.
DRGs, though, cannot account for all variation in costs among patients
other characteristics of patients other than their DRG and the hospital where they
t explain their costs.
Some of these characteristics will be of general relevance, such as the patient’s age,
economic status. Hvenegaard et al. (2009) consider the additional
explanatory power, over and above that offered by the DRG classification, in
explaining variation in the costs of patients undergoing vascular surgery. In this
study, such variables prove to add little additional information. This is consistent
with the health insurance literature, where age and gender explain little of the
individual risk of incurring health expenditure.
Other patient characteristics are more important, and are likely to vary according to
the condition under consideration. For example Hvenegaard et al. (2009)
set of characteristics relevant to vascular patients including their sm
The HealthBASKET project has explored in depth the relevance of diagnostics and
ent level) as well as certain structural variables: For hip
replacement, the choice of cemented vs. non-cemented hip implants as well as the
number of hospital beds were significant explanatory factors (Stargardt 2008)
ceiving thrombolysis and length of stay were significant explanatory
(Epstein et al. 2008). For acute myocardial infarction (AMI), these were the
of PTCA and stenting, length of stay, and the setting (i.e. urban/rural)
. For normal child delivery, the variables length
labour costs for nurses/midwives were significant (Bellanger and Or 2008)
appendectomy, open surgery (vs. laparoscopic surgery) was associated with
significantly lower costs, whereas a larger number of hospital beds led to higher
. For cataract surgery, the number of minutes used for the
intervention had the highest explanatory power (Fattore and Torbica 2008)
9
is a vector of dummy variables specifying the DRG to which the patient is
is variation in cost that is attributable to the hospital in which the
DRGs, though, cannot account for all variation in costs among patients – there will be
other characteristics of patients other than their DRG and the hospital where they
Some of these characteristics will be of general relevance, such as the patient’s age,
consider the additional
d above that offered by the DRG classification, in
explaining variation in the costs of patients undergoing vascular surgery. In this
study, such variables prove to add little additional information. This is consistent
where age and gender explain little of the
Other patient characteristics are more important, and are likely to vary according to
(2009) consider a
set of characteristics relevant to vascular patients including their smoking status,
The HealthBASKET project has explored in depth the relevance of diagnostics and
ent level) as well as certain structural variables: For hip
cemented hip implants as well as the
(Stargardt 2008). For
stay were significant explanatory
. For acute myocardial infarction (AMI), these were the
the setting (i.e. urban/rural) of the
. For normal child delivery, the variables length of stay and
(Bellanger and Or 2008). For
(vs. laparoscopic surgery) was associated with
a larger number of hospital beds led to higher
number of minutes used for the
(Fattore and Torbica 2008). Similarly
Determinants of hospital costs and performance variation
Laudicella et al. (2009) – besides patient variables such as birth weight and whether
or not the baby was still
variables in their analysis of the costs of patients admitted to obstetrics specialties,
together with a set of hospital variables specific to obstetrics, including the number
of babies delivered.
3.2 Hospital characteristics
The choice about what hospital characteristics,
the purpose or perspective of the analysis. Broadly, the literature can be divided into
two camps: technological functions derived from the th
behavioural functions designed to control for the exogenous constraints that
prohibit cost minimization among hospitals.
A standard neo-classical framework involves explaining costs in relation to the level
of production (e.g. number of patients treated) and the price of different inputs
notably labour, equipment and capital. If the research interest is in analysing costs
from the perspective of hospitals themselves, this framework might be appropriate.
The explanatory variables
the hospitals themselves.
Early studies of hospital costs specified a behavioural function in a somewhat
manner, including “fairly indiscriminately all variables for which a causal relationship
to hospital costs is hypothesized and data are available”
more thought has gone into the specification, in recognition that, in most public
health systems, some hospitals are required to operate in more adverse
circumstances than others. These circumstances are often termed
factors” and make achievement of a given level of cost more difficult. In effect these
factors constrain the hospital from operating on the technically feasible minimum
cost frontier.
The analytical objective is to control for these constra
between hospitals. This involves identifying a set of variables that reflects feasible
production possibilities within a constrained environment
often considerable debate as to what factors are considered constraints. In the short
eterminants of hospital costs and performance variation
besides patient variables such as birth weight and whether
or not the baby was still-born – consider a range of diagnostic and procedural
variables in their analysis of the costs of patients admitted to obstetrics specialties,
together with a set of hospital variables specific to obstetrics, including the number
Hospital characteristics
The choice about what hospital characteristics, kmz , to take into account depends on
the purpose or perspective of the analysis. Broadly, the literature can be divided into
two camps: technological functions derived from the theory of the firm and so
functions designed to control for the exogenous constraints that
prohibit cost minimization among hospitals.
classical framework involves explaining costs in relation to the level
mber of patients treated) and the price of different inputs
notably labour, equipment and capital. If the research interest is in analysing costs
from the perspective of hospitals themselves, this framework might be appropriate.
The explanatory variables measure the input choices made by – or endogenous to
Early studies of hospital costs specified a behavioural function in a somewhat
manner, including “fairly indiscriminately all variables for which a causal relationship
to hospital costs is hypothesized and data are available” (Breyer 1987)
more thought has gone into the specification, in recognition that, in most public
health systems, some hospitals are required to operate in more adverse
circumstances than others. These circumstances are often termed “
and make achievement of a given level of cost more difficult. In effect these
factors constrain the hospital from operating on the technically feasible minimum
The analytical objective is to control for these constraining factors in comparing costs
between hospitals. This involves identifying a set of variables that reflects feasible
production possibilities within a constrained environment (Smith 1981)
often considerable debate as to what factors are considered constraints. In the short
10
besides patient variables such as birth weight and whether
f diagnostic and procedural
variables in their analysis of the costs of patients admitted to obstetrics specialties,
together with a set of hospital variables specific to obstetrics, including the number
, to take into account depends on
the purpose or perspective of the analysis. Broadly, the literature can be divided into
of the firm and so-called
functions designed to control for the exogenous constraints that
classical framework involves explaining costs in relation to the level
mber of patients treated) and the price of different inputs –
notably labour, equipment and capital. If the research interest is in analysing costs
from the perspective of hospitals themselves, this framework might be appropriate.
or endogenous to -
Early studies of hospital costs specified a behavioural function in a somewhat ad hoc
manner, including “fairly indiscriminately all variables for which a causal relationship
(Breyer 1987). But recently
more thought has gone into the specification, in recognition that, in most public
health systems, some hospitals are required to operate in more adverse
“environmental
and make achievement of a given level of cost more difficult. In effect these
factors constrain the hospital from operating on the technically feasible minimum
ining factors in comparing costs
between hospitals. This involves identifying a set of variables that reflects feasible
(Smith 1981). There is
often considerable debate as to what factors are considered constraints. In the short
Determinants of hospital costs and performance variation
run, many factors are outside the control of hospitals. In
set of factors is potentially under hospital control, but the extent and nature of this
control will vary depending on the nature of the context.
In what follows, we consider in more detail the type of variables that might be
incorporated in the vector
3.2.1 Teaching status
Teaching hospitals are often thought to have higher costs than non
hospitals. There have been numerous studies devoted to estimating the cost
differential and almost all econometr
status as a dummy variable. We do not attempt an exhaustive summary of this
empirical research, except to say that the literature rarely explains why costs might
differ in these two types of institution. There
differential costs.
The first reason is not to do with the teaching function of the hospital
perceived inadequacies in DRG system. Teaching hospitals are thought to treat
patients of a greater severity than non
should be able to account for these differences. In practice, the classification may be
imperfect. If teaching hospitals systematically attract more severe patients within
each DRG, their costs will be higher.
picking up additional patient heterogeneity, rather than it having anything to do with
the teaching function itself.
The second reason is due to how teaching is funded. As part of their training medical
students are required to accompany consultants around the hospital in order to
observe and treat patients. Thus the provision of teaching may introduce delays to
the treatment process if, say, consultants spend longer reviewing each patient prior
to surgery or prior to discharge so that the medical students can learn from the
review process. In essence, the provision of patient care and medical education is a
joint and complementary process and it is not straightforward to disentangle these
two components.
eterminants of hospital costs and performance variation
run, many factors are outside the control of hospitals. In the longer term a broader
set of factors is potentially under hospital control, but the extent and nature of this
control will vary depending on the nature of the context.
In what follows, we consider in more detail the type of variables that might be
rporated in the vector kmz .
Teaching hospitals are often thought to have higher costs than non
hospitals. There have been numerous studies devoted to estimating the cost
differential and almost all econometric analyses of hospital costs include teaching
status as a dummy variable. We do not attempt an exhaustive summary of this
empirical research, except to say that the literature rarely explains why costs might
differ in these two types of institution. There are two main explanations of
The first reason is not to do with the teaching function of the hospital
perceived inadequacies in DRG system. Teaching hospitals are thought to treat
patients of a greater severity than non-teaching hospitals. In theory, the DRG system
should be able to account for these differences. In practice, the classification may be
imperfect. If teaching hospitals systematically attract more severe patients within
each DRG, their costs will be higher. So the “teaching status” variable is simply
picking up additional patient heterogeneity, rather than it having anything to do with
the teaching function itself.
The second reason is due to how teaching is funded. As part of their training medical
are required to accompany consultants around the hospital in order to
observe and treat patients. Thus the provision of teaching may introduce delays to
the treatment process if, say, consultants spend longer reviewing each patient prior
r to discharge so that the medical students can learn from the
review process. In essence, the provision of patient care and medical education is a
joint and complementary process and it is not straightforward to disentangle these
11
the longer term a broader
set of factors is potentially under hospital control, but the extent and nature of this
In what follows, we consider in more detail the type of variables that might be
Teaching hospitals are often thought to have higher costs than non-teaching
hospitals. There have been numerous studies devoted to estimating the cost
ic analyses of hospital costs include teaching
status as a dummy variable. We do not attempt an exhaustive summary of this
empirical research, except to say that the literature rarely explains why costs might
are two main explanations of
The first reason is not to do with the teaching function of the hospital per se, but to
perceived inadequacies in DRG system. Teaching hospitals are thought to treat
teaching hospitals. In theory, the DRG system
should be able to account for these differences. In practice, the classification may be
imperfect. If teaching hospitals systematically attract more severe patients within
variable is simply
picking up additional patient heterogeneity, rather than it having anything to do with
The second reason is due to how teaching is funded. As part of their training medical
are required to accompany consultants around the hospital in order to
observe and treat patients. Thus the provision of teaching may introduce delays to
the treatment process if, say, consultants spend longer reviewing each patient prior
r to discharge so that the medical students can learn from the
review process. In essence, the provision of patient care and medical education is a
joint and complementary process and it is not straightforward to disentangle these
Determinants of hospital costs and performance variation
If funding fails to determine accurately the costs of teaching, the error will be
captured by the “teaching status
costs. In contexts where medical education is underfunded relative to patient care,
teaching hospitals will have higher costs than non
contexts, funding for medical education might be more generous, to the extent that
it subsidizes the provision of patient care. In such circumstances, costs of treatment
in teaching hospitals will appear lower than in non
3.2.2 Ownership
The famous question of whether “there is
2001) between the performance of for
hospitals has yet to be solved
examined differences with regard to organ
Econometric analyses tend to include ownership as a dummy variable either being
specified as private versus public or as for
following we will refer only to for
arguments for both taxonomies are very similar). As for teaching status, we do not
attempt to summarize the findings of all existing studies, bu
implicit conceptual underpinnings, which are
There are two main predictions with regard to cost differences between for
and not-for-profit. The first argues that for
and are more efficient than not
for-profit hospitals operate at lower cost per case.
Three main reasons are put forward to explain why for
operate at lower costs. (1) T
hospitals produce at lower costs as well
with a higher propensity to invest in cost
personally from the resulting profi
hospitals the lack of monitoring by private owners and capital markets means that
managers are less tightly controlled and therefore have more opportunities to shirk.
(3) Related but slightly different
reputation in the community rather than profit maxim
eterminants of hospital costs and performance variation
ng fails to determine accurately the costs of teaching, the error will be
teaching status” variable in the analysis of patient-related hospital
costs. In contexts where medical education is underfunded relative to patient care,
spitals will have higher costs than non-teaching hospitals. In other
contexts, funding for medical education might be more generous, to the extent that
s the provision of patient care. In such circumstances, costs of treatment
tals will appear lower than in non-teaching hospitals.
whether “there is a dime’s worth of difference”
between the performance of for-profit and not-for-profit or public and private
solved. Many theoretical and empirical investigations have
differences with regard to organizational goals, behaviour and outcomes.
Econometric analyses tend to include ownership as a dummy variable either being
specified as private versus public or as for-profit versus not-for
following we will refer only to for-profit and not-for-profit differences as the
arguments for both taxonomies are very similar). As for teaching status, we do not
the findings of all existing studies, but rather focus on the
implicit conceptual underpinnings, which are rarely spelled out explicitly.
There are two main predictions with regard to cost differences between for
profit. The first argues that for-profit hospitals operate at lo
and are more efficient than not-for-profit ones. The second argues the opposite: not
profit hospitals operate at lower cost per case.
Three main reasons are put forward to explain why for-profit hospitals should
operate at lower costs. (1) The property rights model suggests that for
hospitals produce at lower costs as well-established control rights provide owners
with a higher propensity to invest in cost-cutting innovations since they stand to gain
personally from the resulting profits. (2) It is argued that in public and not
hospitals the lack of monitoring by private owners and capital markets means that
managers are less tightly controlled and therefore have more opportunities to shirk.
(3) Related but slightly different is the argument that quality and institutional
reputation in the community rather than profit maximization are predominant
12
ng fails to determine accurately the costs of teaching, the error will be
related hospital
costs. In contexts where medical education is underfunded relative to patient care,
teaching hospitals. In other
contexts, funding for medical education might be more generous, to the extent that
s the provision of patient care. In such circumstances, costs of treatment
dime’s worth of difference” (Sloan et al.
profit or public and private
oretical and empirical investigations have
tional goals, behaviour and outcomes.
Econometric analyses tend to include ownership as a dummy variable either being
for-profit (in the
profit differences as the
arguments for both taxonomies are very similar). As for teaching status, we do not
t rather focus on the
rarely spelled out explicitly.
There are two main predictions with regard to cost differences between for-profit
profit hospitals operate at lower costs
profit ones. The second argues the opposite: not-
profit hospitals should
he property rights model suggests that for-profit
established control rights provide owners
cutting innovations since they stand to gain
ts. (2) It is argued that in public and not-for-profit
hospitals the lack of monitoring by private owners and capital markets means that
managers are less tightly controlled and therefore have more opportunities to shirk.
is the argument that quality and institutional
tion are predominant
Determinants of hospital costs and performance variation
principles for evaluating managers in the public sector and these determine
managers’ career advancement. As a consequence managers
profit hospitals face strong incentives to invest time and resources to maxim
reputation enhancing technologies or representative infrastructure rather than
focusing on profits or efficiency.
The second prediction, based on a numb
systematic reviews and meta
that “public rather than private provision of health care seems more efficient for
hospitals” (Hollingsworth 2008)
findings, this strand of the literature argues that the finding of “higher profits”
among for-profit hospitals are neither due to true costs nor due to ownership
structure per se. Rather they are due to not
attracting more complex or severe patients and of the inadequacy of DRGs to reflect
actual costs and greater (unobserved) severity of these patients. In such
circumstances, costs of treatment in not
in for-profit hospitals. Accounting for these imperfections reveals that public
hospitals operate at least as efficiently as they ha
pick less complex patients.
Contract failure models add that as the quality and adequacy health care service
hard to determine for patients
characterized by information asymmetry in favour of suppliers
framework, for-profit hospitals face incentives to increase profit at the cost of lower
quality of care, while not
nondistribution constraint, have no incentive to lower quality in fa
(Wörz 2008: 37-38). As a consequence this set of models pred
profits are higher in for-profit hospitals while efficiency (if taking account of quality
when measuring costs or ideally being measured in terms of health outcomes) will
be lower. There is empirical evidence from a meta
(Devereaux et al. 2002).
eterminants of hospital costs and performance variation
principles for evaluating managers in the public sector and these determine
managers’ career advancement. As a consequence managers in public and not
profit hospitals face strong incentives to invest time and resources to maxim
reputation enhancing technologies or representative infrastructure rather than
focusing on profits or efficiency.
The second prediction, based on a number of empirical observations including
systematic reviews and meta-analyses (Hollingsworth 2003; Vaillancourt 2003)
n private provision of health care seems more efficient for
(Hollingsworth 2008). Building on a mixture of theoretical and empirica
findings, this strand of the literature argues that the finding of “higher profits”
profit hospitals are neither due to true costs nor due to ownership
structure per se. Rather they are due to not-for-profit hospitals systematically
more complex or severe patients and of the inadequacy of DRGs to reflect
actual costs and greater (unobserved) severity of these patients. In such
circumstances, costs of treatment in not-for-profit hospitals will appear higher than
. Accounting for these imperfections reveals that public
hospitals operate at least as efficiently as they have no ability or incentives to cherry
less complex patients.
Contract failure models add that as the quality and adequacy health care service
hard to determine for patients (Hansmann 1980) as health care markets are
characterized by information asymmetry in favour of suppliers, i.e. hospitals. In this
profit hospitals face incentives to increase profit at the cost of lower
quality of care, while not-for-profit hospitals, being characterized by a
nondistribution constraint, have no incentive to lower quality in fa
. As a consequence this set of models predict that revenue and
profit hospitals while efficiency (if taking account of quality
when measuring costs or ideally being measured in terms of health outcomes) will
be lower. There is empirical evidence from a meta-analysis suppo
13
principles for evaluating managers in the public sector and these determine
in public and not-for-
profit hospitals face strong incentives to invest time and resources to maximize
reputation enhancing technologies or representative infrastructure rather than
er of empirical observations including
(Hollingsworth 2003; Vaillancourt 2003) , is
n private provision of health care seems more efficient for
. Building on a mixture of theoretical and empirical
findings, this strand of the literature argues that the finding of “higher profits”
profit hospitals are neither due to true costs nor due to ownership
profit hospitals systematically
more complex or severe patients and of the inadequacy of DRGs to reflect
actual costs and greater (unobserved) severity of these patients. In such
profit hospitals will appear higher than
. Accounting for these imperfections reveals that public
ve no ability or incentives to cherry-
Contract failure models add that as the quality and adequacy health care services are
as health care markets are
, i.e. hospitals. In this
profit hospitals face incentives to increase profit at the cost of lower
profit hospitals, being characterized by a
nondistribution constraint, have no incentive to lower quality in favour of profits
ict that revenue and
profit hospitals while efficiency (if taking account of quality
when measuring costs or ideally being measured in terms of health outcomes) will
analysis supporting this view
Determinants of hospital costs and performance variation
Institutional approaches furthe
regimes may have different costs because they are subject to different taxation
regimes, may have different access to capital, may have differential influence on
labour costs, their location of production, o
compensated) emergency care provided
circumstances mean that for
then depends on the context spec
In contexts where patient and organ
differences in factors constraining the behaviour of for
hospitals, the error will be captured by
If for-profit hospital face a less constraining environment or benefit from more
effective incentive structures relative to not
will have lower costs than not
more favourable regulatory environment (e.g. generous tax breaks) relative to for
profit hospitals, not-for-profit hospitals will have lower costs than for
3.2.3 Volume of activity: economies of scale
Larger hospitals or units are often thought to produce at lower costs than smaller
hospitals or units. The basic argument is that larger hospitals or units benefit from
economies of scale, experiencing decreasing costs per output as volume increases.
Larger hospitals or units might produce at lower cost due to the following reasons:
specialized equipment often comes in units of some minimum size, so that larger
output makes usage more efficient. Benefits from division of labour may arise
because larger workforce fac
each individual worker allowing for standard
technological infrastructure may allow compensating more easily for illnesses or
departure of workers or technological
Beyond a particular size, diseconomies of scale may arise, perhaps because a larger
hospital or unit size leads to overly high expenditures for overhead, bureaucratic
forms of organization, complex interdependencies implying problems of
coordination and cooperation.
eterminants of hospital costs and performance variation
Institutional approaches further stress that hospitals with different ownership
regimes may have different costs because they are subject to different taxation
regimes, may have different access to capital, may have differential influence on
labour costs, their location of production, or the amount of (inadequately
compensated) emergency care provided (Mason et al. 2008a). Whether these
circumstances mean that for-profit or not-for-profit hospitals produce at higher cost
then depends on the context specific configurations of the regulatory framework.
In contexts where patient and organizational variables fail to adequately reflect
differences in factors constraining the behaviour of for-profit and not
hospitals, the error will be captured by the dummy variable “ownership status”.
profit hospital face a less constraining environment or benefit from more
effective incentive structures relative to not-for-profit hospitals, for-
will have lower costs than not-for-profit hospitals. If not-for-profit hospitals face a
more favourable regulatory environment (e.g. generous tax breaks) relative to for
profit hospitals will have lower costs than for-
Volume of activity: economies of scale
spitals or units are often thought to produce at lower costs than smaller
hospitals or units. The basic argument is that larger hospitals or units benefit from
economies of scale, experiencing decreasing costs per output as volume increases.
ls or units might produce at lower cost due to the following reasons:
specialized equipment often comes in units of some minimum size, so that larger
output makes usage more efficient. Benefits from division of labour may arise
because larger workforce facilitates restricting the range of services performed by
each individual worker allowing for standardization. Also a larger workforce and
technological infrastructure may allow compensating more easily for illnesses or
departure of workers or technological problems.
Beyond a particular size, diseconomies of scale may arise, perhaps because a larger
hospital or unit size leads to overly high expenditures for overhead, bureaucratic
forms of organization, complex interdependencies implying problems of
tion and cooperation.
14
r stress that hospitals with different ownership
regimes may have different costs because they are subject to different taxation
regimes, may have different access to capital, may have differential influence on
r the amount of (inadequately
. Whether these
profit hospitals produce at higher cost
ific configurations of the regulatory framework.
tional variables fail to adequately reflect
profit and not-for profit
my variable “ownership status”.
profit hospital face a less constraining environment or benefit from more
-profit hospitals
profit hospitals face a
more favourable regulatory environment (e.g. generous tax breaks) relative to for-
-profits.
spitals or units are often thought to produce at lower costs than smaller
hospitals or units. The basic argument is that larger hospitals or units benefit from
economies of scale, experiencing decreasing costs per output as volume increases.
ls or units might produce at lower cost due to the following reasons:
specialized equipment often comes in units of some minimum size, so that larger
output makes usage more efficient. Benefits from division of labour may arise
ilitates restricting the range of services performed by
tion. Also a larger workforce and
technological infrastructure may allow compensating more easily for illnesses or
Beyond a particular size, diseconomies of scale may arise, perhaps because a larger
hospital or unit size leads to overly high expenditures for overhead, bureaucratic
forms of organization, complex interdependencies implying problems of
Determinants of hospital costs and performance variation
There have been numerous studies devoted to these issues, e.g.
almost all econometric analyses of hospital costs include some measure of size as a
dummy variable. To scrutin
the number of patients (e.g. in thousands) treated in hospital or department
model. These outlined arguments may also be consistently formulated to justify a
variable that captures the volume of a specific episode of care. Hence one should
add a variable that measures the number of patients falling in the definition of the
respective episode of care treated in the hospital or department
by episode of care.
If one of the respective variables is positive, this suggests that average costs after
controlling for patient characteristics are higher in large departments or hospitals or
in departments producing more of the services relevant to the respective episode
care. Additionally, a measure for the number of whole time equivalent general or
specialist physician per 100 patients can be incorporated if reported. Different job
and staff categories can be weighted according to their respective wages.
Whether size should be considered truly
regulatory context. In some countries as in Germany hospital capacity is negotiated
between state-level regulators and hospital management and then fixed for a certain
period of time. Hence, in the short
it might be adjusted.
3.2.4 Range of activity: special
The range of activity offered by the hospital may also influence costs, but it is
difficult to predict the
economies of scope, increasing the range of activity leads to lower costs. Economies
of scope refer to a situation in which the joint production of two or more products
can be achieved at lower costs th
individually. General hospitals offering a wide range of services may produce at
lower costs in circumstances in which the production of different but related outputs
jointly is cheaper than the production of
These cost advantages can be generated through shared use of resources
technology, workers, or general overhead such as spreading fix costs of operating
eterminants of hospital costs and performance variation
There have been numerous studies devoted to these issues, e.g. (Posnett 2002)
almost all econometric analyses of hospital costs include some measure of size as a
dummy variable. To scrutinize the effect to different hospital sizes one can include
the number of patients (e.g. in thousands) treated in hospital or department
model. These outlined arguments may also be consistently formulated to justify a
variable that captures the volume of a specific episode of care. Hence one should
add a variable that measures the number of patients falling in the definition of the
ective episode of care treated in the hospital or department j measuring volume
If one of the respective variables is positive, this suggests that average costs after
controlling for patient characteristics are higher in large departments or hospitals or
in departments producing more of the services relevant to the respective episode
care. Additionally, a measure for the number of whole time equivalent general or
specialist physician per 100 patients can be incorporated if reported. Different job
and staff categories can be weighted according to their respective wages.
should be considered truly environmental factors depends to on the
regulatory context. In some countries as in Germany hospital capacity is negotiated
level regulators and hospital management and then fixed for a certain
e, in the short-run capacity, is exogenous, while in the long run
Range of activity: specialization versus economies of scope
The range of activity offered by the hospital may also influence costs, but it is
difficult to predict the direction of influence. On the one hand, if there are
economies of scope, increasing the range of activity leads to lower costs. Economies
of scope refer to a situation in which the joint production of two or more products
can be achieved at lower costs than the combined cost of producing each product
individually. General hospitals offering a wide range of services may produce at
lower costs in circumstances in which the production of different but related outputs
jointly is cheaper than the production of outputs separately (Panzar and Willig 1981)
These cost advantages can be generated through shared use of resources
technology, workers, or general overhead such as spreading fix costs of operating
15
(Posnett 2002) and
almost all econometric analyses of hospital costs include some measure of size as a
the effect to different hospital sizes one can include
the number of patients (e.g. in thousands) treated in hospital or department j in the
model. These outlined arguments may also be consistently formulated to justify a
variable that captures the volume of a specific episode of care. Hence one should
add a variable that measures the number of patients falling in the definition of the
measuring volume
If one of the respective variables is positive, this suggests that average costs after
controlling for patient characteristics are higher in large departments or hospitals or
in departments producing more of the services relevant to the respective episode of
care. Additionally, a measure for the number of whole time equivalent general or
specialist physician per 100 patients can be incorporated if reported. Different job
and staff categories can be weighted according to their respective wages.
environmental factors depends to on the
regulatory context. In some countries as in Germany hospital capacity is negotiated
level regulators and hospital management and then fixed for a certain
run capacity, is exogenous, while in the long run
The range of activity offered by the hospital may also influence costs, but it is
direction of influence. On the one hand, if there are
economies of scope, increasing the range of activity leads to lower costs. Economies
of scope refer to a situation in which the joint production of two or more products
an the combined cost of producing each product
individually. General hospitals offering a wide range of services may produce at
lower costs in circumstances in which the production of different but related outputs
(Panzar and Willig 1981).
These cost advantages can be generated through shared use of resources such as
technology, workers, or general overhead such as spreading fix costs of operating
Determinants of hospital costs and performance variation
rooms or intensive care units over multiple different but related operations. So, for
example, it might be less exp
department, fracture clinic
rather than having them in different locations, as this means that equipment be
shared and staff in different departments can work more effectively together
particularly when patients need to transferred between each setting.
On the other hand, it is often argued that hospitals which special
than general hospitals (Dranove 1987)
ring-fence resources for specific purposes,
competing claims on their use
2009). Another argument is that special
flourish. Specialist hospitals may be better at evaluating practice over a more limited
range of activities and clinical outcomes have been shown improve as doctors
undertake more of the same procedure.
To analyse the effect of different range of services the number of specialties offered
in a hospital can be used as a proxy.
average costs after controlling for patient characteristics are higher in hospitals with
more specialities. Another approach is to define a special
distribution of activity across DRGs
Laudicella et al. (2009: 8) include variables that measure the amount of neonatal and
antenatal care as a proportion of all activity in the obstetrics department.
3.2.5 Quality
One reason that costs may differ among hospitals is that their quality di
relationship between quality and costs
section on ownership, some models envisage that higher quality implies higher
resource consumption, while other models suggest that higher quality can lead to
more efficient delivery of hospital care
between quality and owner
al. 2002; Vaillancourt 2003)
conduciveness of different forms of ownership on quality.
eterminants of hospital costs and performance variation
rooms or intensive care units over multiple different but related operations. So, for
example, it might be less expensive to situate the accident and
tment, fracture clinic, and trauma and orthopaedic wards in close proximity
rather than having them in different locations, as this means that equipment be
shared and staff in different departments can work more effectively together
nts need to transferred between each setting.
On the other hand, it is often argued that hospitals which specialize have lower costs
(Dranove 1987). One reason for specialization is to protect or
fence resources for specific purposes, when otherwise there would be
competing claims on their use (Harris 1977; Kjekshus and Hagen 2005; Street et
. Another argument is that specialization allows expertise to develop and
flourish. Specialist hospitals may be better at evaluating practice over a more limited
range of activities and clinical outcomes have been shown improve as doctors
undertake more of the same procedure.
effect of different range of services the number of specialties offered
in a hospital can be used as a proxy. If positive, this variable would suggest that
average costs after controlling for patient characteristics are higher in hospitals with
Another approach is to define a specialization index, capturing the
distribution of activity across DRGs (Daidone and D'Amico 2009). In a similar vein,
include variables that measure the amount of neonatal and
antenatal care as a proportion of all activity in the obstetrics department.
One reason that costs may differ among hospitals is that their quality di
relationship between quality and costs, however, is unclear. As outlined in the
section on ownership, some models envisage that higher quality implies higher
resource consumption, while other models suggest that higher quality can lead to
fficient delivery of hospital care (Wörz 2008). Moreover, the relationship
between quality and ownership is a frequent issue (Currie et al. 2003; Devereaux et
al. 2002; Vaillancourt 2003). However, the evidence is inconclusive with regard the
conduciveness of different forms of ownership on quality.
16
rooms or intensive care units over multiple different but related operations. So, for
ensive to situate the accident and emergency
orthopaedic wards in close proximity
rather than having them in different locations, as this means that equipment be
shared and staff in different departments can work more effectively together
have lower costs
tion is to protect or
when otherwise there would be
(Harris 1977; Kjekshus and Hagen 2005; Street et al.
tion allows expertise to develop and
flourish. Specialist hospitals may be better at evaluating practice over a more limited
range of activities and clinical outcomes have been shown improve as doctors
effect of different range of services the number of specialties offered
If positive, this variable would suggest that
average costs after controlling for patient characteristics are higher in hospitals with
tion index, capturing the
. In a similar vein,
include variables that measure the amount of neonatal and
antenatal care as a proportion of all activity in the obstetrics department.
One reason that costs may differ among hospitals is that their quality differs. The
is unclear. As outlined in the
section on ownership, some models envisage that higher quality implies higher
resource consumption, while other models suggest that higher quality can lead to
. Moreover, the relationship
(Currie et al. 2003; Devereaux et
. However, the evidence is inconclusive with regard the
Determinants of hospital costs and performance variation
For the analyses in the EuroDRG project it is moreover important to
quality is multi-dimensional and difficult to measure as it is difficult to establish both
the direction and degree of influence of quality on costs.
Preferably measures of quality will be available for each patient, in which case
influence can be established by including the measures in the
explaining patient costs in equation (3). Various measures of quality can be
considered including waiting times, in
readmissions, and changes in health status.
In the absence of patient
process of care delivery or structure
delivered. These measures might describe, say, whether clinical guidelines have been
adopted, the staffing complement, or the
equipment (see section 3.2.6). Whatever the measure, there is an assumption that
investment in process or structural dimensions of quality is positively correlated with
the quality of care delivered to individual patien
3.2.6 Technological equipment
The relationship between hospital costs and technological equipment has been on
the research agenda for several decades. Many of the investigations were and some
are still inspired by the idea of non
Luft et al. 1986). The latter argue that, as in most western health systems patients
are not sensitive to hospital prices (since they are insured) and the quality of care
delivered tends to be hard to judge, hospitals can feel motivated to (over
“high technology” as a competitive strategy to attract (profitable) patients. This may
result in a “medical arms race”
may increase costs per case.
At the same time it has been stressed that technology investments in hospitals may
encompass product, process and organizational innovation that can be hypothesized
to influence hospitals in very different ways
equipment may increase total costs per case but may also decrease total costs per
case. Similarly process and organizational innovation can be hypothesized to
eterminants of hospital costs and performance variation
For the analyses in the EuroDRG project it is moreover important to
dimensional and difficult to measure as it is difficult to establish both
the direction and degree of influence of quality on costs.
Preferably measures of quality will be available for each patient, in which case
an be established by including the measures in the ikx vector of variables
explaining patient costs in equation (3). Various measures of quality can be
considered including waiting times, in-hospital or 30-day mortality, infections,
readmissions, and changes in health status.
In the absence of patient-level measures of quality, some studies describe the
or structure of the department or hospital in which care is
delivered. These measures might describe, say, whether clinical guidelines have been
adopted, the staffing complement, or the availability of particular types of
equipment (see section 3.2.6). Whatever the measure, there is an assumption that
investment in process or structural dimensions of quality is positively correlated with
the quality of care delivered to individual patients.
Technological equipment
The relationship between hospital costs and technological equipment has been on
the research agenda for several decades. Many of the investigations were and some
are still inspired by the idea of non-price competition among hospitals
. The latter argue that, as in most western health systems patients
are not sensitive to hospital prices (since they are insured) and the quality of care
to be hard to judge, hospitals can feel motivated to (over
“high technology” as a competitive strategy to attract (profitable) patients. This may
result in a “medical arms race”, which can cause higher hospital expenditure and
s per case.
At the same time it has been stressed that technology investments in hospitals may
encompass product, process and organizational innovation that can be hypothesized
to influence hospitals in very different ways (Zweifel and Breyer 1997)
equipment may increase total costs per case but may also decrease total costs per
case. Similarly process and organizational innovation can be hypothesized to
17
For the analyses in the EuroDRG project it is moreover important to consider that
dimensional and difficult to measure as it is difficult to establish both
Preferably measures of quality will be available for each patient, in which case
vector of variables
explaining patient costs in equation (3). Various measures of quality can be
day mortality, infections,
easures of quality, some studies describe the
of the department or hospital in which care is
delivered. These measures might describe, say, whether clinical guidelines have been
availability of particular types of
equipment (see section 3.2.6). Whatever the measure, there is an assumption that
investment in process or structural dimensions of quality is positively correlated with
The relationship between hospital costs and technological equipment has been on
the research agenda for several decades. Many of the investigations were and some
pitals (Joskow 1983;
. The latter argue that, as in most western health systems patients
are not sensitive to hospital prices (since they are insured) and the quality of care
to be hard to judge, hospitals can feel motivated to (over-) invest in
“high technology” as a competitive strategy to attract (profitable) patients. This may
which can cause higher hospital expenditure and
At the same time it has been stressed that technology investments in hospitals may
encompass product, process and organizational innovation that can be hypothesized
(Zweifel and Breyer 1997). Technological
equipment may increase total costs per case but may also decrease total costs per
case. Similarly process and organizational innovation can be hypothesized to
Determinants of hospital costs and performance variation
increase or decrease costs per c
hard to justify any general statement about the expected relationship between
hospital costs and technology or technical equipment.
The multidimensional character of technology is one of the reasons why
technological indices - in its simplest form the sum of the number of services each
hospital offers from a list of possible services
account for the heterogeneity of technology
underlying hypothesis suggesting a specific relation between technology on the one
side and hospital costs on the other side can hardly be specified, which undermines
well-grounded modelling.
A common alternative is the use of specific technology indices, which are modelled
from a vector of known efficacious technologies at the level of the hospital
et al. 1994; Prince 1998)
variables is problematic when used to explain cost v
main reason is that technologies or technological equipment to be included are
commonly selected in a more or less arbitrary way, while at the same time empirical
studies confirms that variable omission and variable selectio
technology substantially affect the results of parametric hospital cost functions
(Cremieux and Ouellette 2001)
The episode of care approach seems well suited to avoid the main drawbacks of the
outlined approaches. Firstly, as the costs of specific indications or are to be
explained, the range of tech
is limited and decisions for including certain types of technical equipment can be
more readily justified by reference to the treatment patterns of the episode at hand.
The arbitrariness of the variable
remains a matter of degree. Moreover, practical experience within hospitals and
episode specific costing studies may be used to formulate well
about the relationship between specific t
costs. This makes it easier to justify the inclusion of specific variables approximating
technological equipment during the modelling process.
eterminants of hospital costs and performance variation
increase or decrease costs per case. Given the theoretical background it seems to be
hard to justify any general statement about the expected relationship between
hospital costs and technology or technical equipment.
The multidimensional character of technology is one of the reasons why
in its simplest form the sum of the number of services each
hospital offers from a list of possible services - are criticized as they are not able to
account for the heterogeneity of technology (Spetz and Maiuro 2004)
underlying hypothesis suggesting a specific relation between technology on the one
side and hospital costs on the other side can hardly be specified, which undermines
elling.
A common alternative is the use of specific technology indices, which are modelled
from a vector of known efficacious technologies at the level of the hospital
et al. 1994; Prince 1998). However, also the use of this category of explanatory
variables is problematic when used to explain cost variation between hospitals. The
main reason is that technologies or technological equipment to be included are
commonly selected in a more or less arbitrary way, while at the same time empirical
studies confirms that variable omission and variable selection with regard to hospital
technology substantially affect the results of parametric hospital cost functions
(Cremieux and Ouellette 2001).
The episode of care approach seems well suited to avoid the main drawbacks of the
outlined approaches. Firstly, as the costs of specific indications or are to be
explained, the range of technologies and technological equipment to be considered
is limited and decisions for including certain types of technical equipment can be
more readily justified by reference to the treatment patterns of the episode at hand.
The arbitrariness of the variable selection seems hence less problematic
remains a matter of degree. Moreover, practical experience within hospitals and
episode specific costing studies may be used to formulate well-grounded hypotheses
about the relationship between specific types of technical equipment and hospital
costs. This makes it easier to justify the inclusion of specific variables approximating
technological equipment during the modelling process.
18
ase. Given the theoretical background it seems to be
hard to justify any general statement about the expected relationship between
The multidimensional character of technology is one of the reasons why general
in its simplest form the sum of the number of services each
are criticized as they are not able to
and Maiuro 2004). Moreover, an
underlying hypothesis suggesting a specific relation between technology on the one
side and hospital costs on the other side can hardly be specified, which undermines
A common alternative is the use of specific technology indices, which are modelled
from a vector of known efficacious technologies at the level of the hospital (Pitterle
. However, also the use of this category of explanatory
ariation between hospitals. The
main reason is that technologies or technological equipment to be included are
commonly selected in a more or less arbitrary way, while at the same time empirical
n with regard to hospital
technology substantially affect the results of parametric hospital cost functions
The episode of care approach seems well suited to avoid the main drawbacks of the
outlined approaches. Firstly, as the costs of specific indications or are to be
nologies and technological equipment to be considered
is limited and decisions for including certain types of technical equipment can be
more readily justified by reference to the treatment patterns of the episode at hand.
selection seems hence less problematic – though it
remains a matter of degree. Moreover, practical experience within hospitals and
grounded hypotheses
ypes of technical equipment and hospital
costs. This makes it easier to justify the inclusion of specific variables approximating
Determinants of hospital costs and performance variation
To scrutinize the effect of diverging sets of technological equipment on hospital
costs, dummy variables for the existence of e.g. a catheter laboratory, a stroke unit
or a neonatal intensive care unit could be included in the model.
3.2.7 Geographical variation in input c
Other factors that make the achievement of a given level of cost or production more
difficult are geographical variations in input costs. So far the empirical evidence
about the significance of differences in input costs is limited and only few DRG
systems attempt to adjust reimbursement for geographical variation. Policy
examples are the US Medicare wage index, which adjusts for differences in hospital
wage levels by a factor reflecting the relative hospital wage level in the geographic
area of the hospital compared to the US
for Medicare and Medicaid Services 2007) and the English “Payment by Results”
(PbR) where public hospitals receive additional payments to account for
geographical variations in the costs of
Market Forces Factor (MFF)
The reason for accounting for input cost differentials across hospitals when
comparing cost per episode of care is that most public hospitals cannot locate where
they wish and therefore need to pay local factor prices rather than relocating to
areas with lower costs. As a result, hospitals face locational constraints, which are
outside their control and affect their production costs
To account for differences in
adjust labour costs of each hospital by a scaling factor that represents variation in
total (or average) costs due local labour market constrains. One way to do this is to
divide the average compensation
regional or state) by the average compensation per hour in the country. Contingent
upon data availability the former can be performed for various job categories and
summarized in a weighted index. The
hospital’s percentage of total costs attributable to salaries to determine final
adjustors. Ultimately final adjustors with scores of less than 1.0 indicate low cost
labour markets and those greater than 1.0 indicate h
example, a hospital with an adjustor of 1.054 is expected to have total costs 5.4%
eterminants of hospital costs and performance variation
the effect of diverging sets of technological equipment on hospital
costs, dummy variables for the existence of e.g. a catheter laboratory, a stroke unit
or a neonatal intensive care unit could be included in the model.
Geographical variation in input costs
Other factors that make the achievement of a given level of cost or production more
difficult are geographical variations in input costs. So far the empirical evidence
about the significance of differences in input costs is limited and only few DRG
stems attempt to adjust reimbursement for geographical variation. Policy
examples are the US Medicare wage index, which adjusts for differences in hospital
wage levels by a factor reflecting the relative hospital wage level in the geographic
spital compared to the US-wide average hospital wage level (Centre
for Medicare and Medicaid Services 2007) and the English “Payment by Results”
(PbR) where public hospitals receive additional payments to account for
geographical variations in the costs of land, buildings and staff through the so
Market Forces Factor (MFF) (Mason et al. 2008b).
The reason for accounting for input cost differentials across hospitals when
comparing cost per episode of care is that most public hospitals cannot locate where
refore need to pay local factor prices rather than relocating to
areas with lower costs. As a result, hospitals face locational constraints, which are
outside their control and affect their production costs (Mason et al. 2008b)
To account for differences in wage levels beyond the control of hospitals one can
adjust labour costs of each hospital by a scaling factor that represents variation in
total (or average) costs due local labour market constrains. One way to do this is to
divide the average compensation per hour in the hospital’s labour market (local,
regional or state) by the average compensation per hour in the country. Contingent
upon data availability the former can be performed for various job categories and
rized in a weighted index. The raw adjustor can then be multiplied by the
hospital’s percentage of total costs attributable to salaries to determine final
adjustors. Ultimately final adjustors with scores of less than 1.0 indicate low cost
labour markets and those greater than 1.0 indicate high cost labour markets. For
example, a hospital with an adjustor of 1.054 is expected to have total costs 5.4%
19
the effect of diverging sets of technological equipment on hospital
costs, dummy variables for the existence of e.g. a catheter laboratory, a stroke unit
Other factors that make the achievement of a given level of cost or production more
difficult are geographical variations in input costs. So far the empirical evidence
about the significance of differences in input costs is limited and only few DRG
stems attempt to adjust reimbursement for geographical variation. Policy
examples are the US Medicare wage index, which adjusts for differences in hospital
wage levels by a factor reflecting the relative hospital wage level in the geographic
wide average hospital wage level (Centre
for Medicare and Medicaid Services 2007) and the English “Payment by Results”
(PbR) where public hospitals receive additional payments to account for
land, buildings and staff through the so-called
The reason for accounting for input cost differentials across hospitals when
comparing cost per episode of care is that most public hospitals cannot locate where
refore need to pay local factor prices rather than relocating to
areas with lower costs. As a result, hospitals face locational constraints, which are
(Mason et al. 2008b)
wage levels beyond the control of hospitals one can
adjust labour costs of each hospital by a scaling factor that represents variation in
total (or average) costs due local labour market constrains. One way to do this is to
per hour in the hospital’s labour market (local,
regional or state) by the average compensation per hour in the country. Contingent
upon data availability the former can be performed for various job categories and
djustor can then be multiplied by the
hospital’s percentage of total costs attributable to salaries to determine final
adjustors. Ultimately final adjustors with scores of less than 1.0 indicate low cost
igh cost labour markets. For
example, a hospital with an adjustor of 1.054 is expected to have total costs 5.4%
Determinants of hospital costs and performance variation
above the country average due to higher labour costs in its labour market. Similarly,
a hospital with an adjustor of 0.98 is expected to experie
due to the local labour market environment. Each hospital’s costs per episode of
care can then be adjusted accordingly. The respective variable
captures differences in the labour prices faced by hospitals in diffe
are beyond their control.
Using similar approach, differences in capital and building costs can be captured
across regions and countries provided that data requirements can be met.
3.2.8 Geographical location
It is common in many empirical a
the location of the hospital. These might identify the geographical area or indicate
whether the hospital is located in an urban or rural setting. The interpretation of the
variables identifying geographical
In some contexts rural hospitals might have higher costs than urban hospitals. For
example, when DRG funding was first introduced in the Australian state of Victoria
rural hospitals received additional payments
reasons for this. First, they were thought to face above ambulance and patient
transport costs simply because they were transporting patients over longer
distances. Second, because they were serving small communit
were less likely to treat sufficient number of patients to achieve economies of scale.
The payment, then, was justified to ensure access to health services for isolated
communities.
In other contexts urban hospitals might appear to have higher costs than their rural
counterparts. This might be because either they attract patients of above
complexity and this is inadequately reflected by the DRG system or they face higher
input prices which have not been adequately accounted for (see preceding section).
It is difficult, though, to see why urban status
variable is likely to capture measurement error in other variables, particularly patient
case-mix, hospital size and scope, and geographical variation in input prices.
eterminants of hospital costs and performance variation
above the country average due to higher labour costs in its labour market. Similarly,
a hospital with an adjustor of 0.98 is expected to experience 2% lower total costs
due to the local labour market environment. Each hospital’s costs per episode of
care can then be adjusted accordingly. The respective variable in the regression
captures differences in the labour prices faced by hospitals in different regions which
Using similar approach, differences in capital and building costs can be captured
across regions and countries provided that data requirements can be met.
Geographical location
It is common in many empirical analyses to include dummy variables that identify
the location of the hospital. These might identify the geographical area or indicate
whether the hospital is located in an urban or rural setting. The interpretation of the
variables identifying geographical area will, of course, be country-specific.
In some contexts rural hospitals might have higher costs than urban hospitals. For
example, when DRG funding was first introduced in the Australian state of Victoria
rural hospitals received additional payments (Duckett 1994). There were two
reasons for this. First, they were thought to face above ambulance and patient
transport costs simply because they were transporting patients over longer
distances. Second, because they were serving small communities rural hospitals
were less likely to treat sufficient number of patients to achieve economies of scale.
The payment, then, was justified to ensure access to health services for isolated
In other contexts urban hospitals might appear to have higher costs than their rural
counterparts. This might be because either they attract patients of above
complexity and this is inadequately reflected by the DRG system or they face higher
prices which have not been adequately accounted for (see preceding section).
It is difficult, though, to see why urban status per se drives higher costs. Rather the
variable is likely to capture measurement error in other variables, particularly patient
mix, hospital size and scope, and geographical variation in input prices.
20
above the country average due to higher labour costs in its labour market. Similarly,
nce 2% lower total costs
due to the local labour market environment. Each hospital’s costs per episode of
in the regression
rent regions which
Using similar approach, differences in capital and building costs can be captured
across regions and countries provided that data requirements can be met.
nalyses to include dummy variables that identify
the location of the hospital. These might identify the geographical area or indicate
whether the hospital is located in an urban or rural setting. The interpretation of the
specific.
In some contexts rural hospitals might have higher costs than urban hospitals. For
example, when DRG funding was first introduced in the Australian state of Victoria
. There were two
reasons for this. First, they were thought to face above ambulance and patient
transport costs simply because they were transporting patients over longer
ies rural hospitals
were less likely to treat sufficient number of patients to achieve economies of scale.
The payment, then, was justified to ensure access to health services for isolated
In other contexts urban hospitals might appear to have higher costs than their rural
counterparts. This might be because either they attract patients of above-average
complexity and this is inadequately reflected by the DRG system or they face higher
prices which have not been adequately accounted for (see preceding section).
drives higher costs. Rather the
variable is likely to capture measurement error in other variables, particularly patient
mix, hospital size and scope, and geographical variation in input prices.
Determinants of hospital costs and performance variation
1 Examining hospital performance
problem
It is often asserted that health care organ
that would otherwise encourage them to innovate and adopt cost minim
behaviour. There are various grounds for making this assertion. For instance,
competitive behaviour may be less in evidence if health care is publi
funded/provided or in situations where health care organ
geographical or specialist monopoly of supply. If competitive pressure is weak, there
may be scope for better util
performance measures such as return on investment (ROI) or profitability seem
inappropriate due to the fact that health care entities are often public or non
profit and therefore do not have to generate profits or returns to investments.
Different classes of models are
hospital performance. Firstly, researchers use models, which attempt to explicitly
model the production process in hospitals and compare (average or total) cost
across hospitals. This group of models build
theory and produced rich and diverse sets of studies. Most popular approaches
include hospital cost function (HCF) analysis operationalized via ordinary least
squares (OLS) or corrected ordinary least squares (COLS) r
These were the main approaches during the 1980s and 1990s to derive insights
about the hospital costs, scale and scope, as well as productivity and efficiency. Over
the last decade the attention of most researchers shifted to performa
Performance analyses aim to identify which organ
others in either their overall operation or in specific areas of operation. This
information may be used to stimulate better use of resources, either by encouragin
organizations to act of their own volition or through the imposition of tailored
incentives by a regulatory authority or funding agency.
eterminants of hospital costs and performance variation
Appendix
hospital performance – the nature of the
It is often asserted that health care organizations face limited competitive pressures
that would otherwise encourage them to innovate and adopt cost minim
behaviour. There are various grounds for making this assertion. For instance,
competitive behaviour may be less in evidence if health care is publi
funded/provided or in situations where health care organizations enjoy a
geographical or specialist monopoly of supply. If competitive pressure is weak, there
may be scope for better utilization of resources. At the same time common
s such as return on investment (ROI) or profitability seem
inappropriate due to the fact that health care entities are often public or non
profit and therefore do not have to generate profits or returns to investments.
Different classes of models are used by health economists to derive insights about
hospital performance. Firstly, researchers use models, which attempt to explicitly
model the production process in hospitals and compare (average or total) cost
across hospitals. This group of models builds mainly on neoclassical microeconomic
theory and produced rich and diverse sets of studies. Most popular approaches
include hospital cost function (HCF) analysis operationalized via ordinary least
squares (OLS) or corrected ordinary least squares (COLS) regression techniques.
These were the main approaches during the 1980s and 1990s to derive insights
about the hospital costs, scale and scope, as well as productivity and efficiency. Over
the last decade the attention of most researchers shifted to performa
Performance analyses aim to identify which organizations are doing better than
others in either their overall operation or in specific areas of operation. This
information may be used to stimulate better use of resources, either by encouragin
tions to act of their own volition or through the imposition of tailored
incentives by a regulatory authority or funding agency.
21
the nature of the
face limited competitive pressures
that would otherwise encourage them to innovate and adopt cost minimizing
behaviour. There are various grounds for making this assertion. For instance,
competitive behaviour may be less in evidence if health care is publicly
tions enjoy a
geographical or specialist monopoly of supply. If competitive pressure is weak, there
tion of resources. At the same time common
s such as return on investment (ROI) or profitability seem
inappropriate due to the fact that health care entities are often public or non-for
profit and therefore do not have to generate profits or returns to investments.
used by health economists to derive insights about
hospital performance. Firstly, researchers use models, which attempt to explicitly
model the production process in hospitals and compare (average or total) cost
s mainly on neoclassical microeconomic
theory and produced rich and diverse sets of studies. Most popular approaches
include hospital cost function (HCF) analysis operationalized via ordinary least
egression techniques.
These were the main approaches during the 1980s and 1990s to derive insights
about the hospital costs, scale and scope, as well as productivity and efficiency. Over
the last decade the attention of most researchers shifted to performance analysis.
tions are doing better than
others in either their overall operation or in specific areas of operation. This
information may be used to stimulate better use of resources, either by encouraging
tions to act of their own volition or through the imposition of tailored
Determinants of hospital costs and performance variation
Here the concept of efficiency is applied to consider the relative performance of
organizations engaged in production, converting inputs into outputs. The
fundamental building block of efficiency analysis is the
production function models the maximum output an organ
given its level and mix of inputs
pictured as in the diagram below. The organ
equipment, etc) and converts these into some sort of output. The middle box, where
this production process takes place
better than others at converting inputs into output.
Labour, intermediate
and capital inputs →
The middle box is actually something of a ´black box´
difficult for outsiders to observe what goes on in the organ
production process is organ
pharmaceutical sector) the production process might be a closely guarded sec
the source of competitive advantage.
This inability to observe the production process directly is a fundamental challenge
for those seeking to analyse efficiency. Nevertheless, it is possible to think of a gold
standard production process that desc
production, given the prevailing technology. This gold standard is termed the
“production frontier”, where the amount and combination of inputs is optimal. Any
other scale of operation or input mix would secure a l
Organizations that have adopted this gold standard are efficient
at the frontier of the prevailing technological process. But organ
operating some way short of this gold standard: equipme
staff may be given to shirking, capital resources might stand idle periodically. These,
and multiple other reasons, might explain inefficiency. To assess whether there is
eterminants of hospital costs and performance variation
efficiency is applied to consider the relative performance of
tions engaged in production, converting inputs into outputs. The
fundamental building block of efficiency analysis is the production function
production function models the maximum output an organization could secure,
given its level and mix of inputs. In very simple terms, the production process can be
pictured as in the diagram below. The organization employs inputs (labour, capital,
equipment, etc) and converts these into some sort of output. The middle box, where
this production process takes place, is critical to whether some organ
better than others at converting inputs into output.
→ Organization of the
production process →
The middle box is actually something of a ´black box´ because it is usually very
difficult for outsiders to observe what goes on in the organization and how its
production process is organized. Indeed, in some industries (such as the
pharmaceutical sector) the production process might be a closely guarded sec
the source of competitive advantage.
This inability to observe the production process directly is a fundamental challenge
for those seeking to analyse efficiency. Nevertheless, it is possible to think of a gold
standard production process that describes the best possible way of organ
production, given the prevailing technology. This gold standard is termed the
, where the amount and combination of inputs is optimal. Any
other scale of operation or input mix would secure a lower ratio of output to input.
tions that have adopted this gold standard are efficient – they are operating
at the frontier of the prevailing technological process. But organiza
operating some way short of this gold standard: equipment might be outmoded,
staff may be given to shirking, capital resources might stand idle periodically. These,
and multiple other reasons, might explain inefficiency. To assess whether there is
22
efficiency is applied to consider the relative performance of
tions engaged in production, converting inputs into outputs. The
production function. The
tion could secure,
. In very simple terms, the production process can be
tion employs inputs (labour, capital,
equipment, etc) and converts these into some sort of output. The middle box, where
, is critical to whether some organizations are
Outputs
because it is usually very
tion and how its
d. Indeed, in some industries (such as the
pharmaceutical sector) the production process might be a closely guarded secret and
This inability to observe the production process directly is a fundamental challenge
for those seeking to analyse efficiency. Nevertheless, it is possible to think of a gold
ribes the best possible way of organizing
production, given the prevailing technology. This gold standard is termed the
, where the amount and combination of inputs is optimal. Any
ower ratio of output to input.
they are operating
izations might be
nt might be outmoded,
staff may be given to shirking, capital resources might stand idle periodically. These,
and multiple other reasons, might explain inefficiency. To assess whether there is
Determinants of hospital costs and performance variation
better scope for utilization of resources, insight can be gaine
organizations involved in similar activities. Rather than
“black box”, such comparative analysis concentrates on the extremes depicted in the
diagram. Information about what goes in (inputs to the production
what comes out (outputs of the production process) allows comparison of input
output combinations of organ
uses less input to produce one unit of output than another organ
is more productive. If we want to assess organ
amounts of output, we need to make judgements about whether there are
economies of scale which, in turn, relies on understanding the gold standard
production process. Organ
efficiency.
2 Specification choices (in parametric analysis of hospital
costs and performance)
We concentrate on specifications choices to be made in the context of the
parametric approaches such as hosp
Analysis (SFA) as these will be used in the EuroDRG project. Similar choices also have
to be made in the context of the Data Envelopment Analysis (DEA). However, as the
EuroDRG project will not apply these we
general terms in section 3 of the appendix and for the complexities of specification
choices refer to the excellent introduction in Jacobs et al.
2.1 Transformation of variables
One of the first choices researchers face is the form in which they incorporate
variables in their model. Using variables in their natural units implies the assumption
that the explanatory variables are related linearly to the dependent variable
et al. 2006: 43). This approach assumes a constant rate of c
scale of activity changes. This assumption may not hold in practice as decreasing
returns to scale or increasing returns to scale or scope can imply variable marginal
cost. Taking logarithms of the variables in the model represents a
linear relationships. In this case, the interpretations of coefficients changes from
eterminants of hospital costs and performance variation
tion of resources, insight can be gained by comparing
tions involved in similar activities. Rather than attempting to
, such comparative analysis concentrates on the extremes depicted in the
diagram. Information about what goes in (inputs to the production
what comes out (outputs of the production process) allows comparison of input
output combinations of organizations that produce similar things. If an organ
uses less input to produce one unit of output than another organization, the for
is more productive. If we want to assess organizations that produce different
amounts of output, we need to make judgements about whether there are
economies of scale which, in turn, relies on understanding the gold standard
production process. Organizations can then be judged in terms of their relative
Specification choices (in parametric analysis of hospital
costs and performance)
We concentrate on specifications choices to be made in the context of the
parametric approaches such as hospital cost functions and the Stochastic Frontier
Analysis (SFA) as these will be used in the EuroDRG project. Similar choices also have
to be made in the context of the Data Envelopment Analysis (DEA). However, as the
EuroDRG project will not apply these we only briefly introduce the DEA in very
general terms in section 3 of the appendix and for the complexities of specification
choices refer to the excellent introduction in Jacobs et al. (2006: 91ff).
Transformation of variables
One of the first choices researchers face is the form in which they incorporate
variables in their model. Using variables in their natural units implies the assumption
that the explanatory variables are related linearly to the dependent variable
. This approach assumes a constant rate of change in costs as the
scale of activity changes. This assumption may not hold in practice as decreasing
returns to scale or increasing returns to scale or scope can imply variable marginal
cost. Taking logarithms of the variables in the model represents a way to model non
linear relationships. In this case, the interpretations of coefficients changes from
23
d by comparing
attempting to prise open the
, such comparative analysis concentrates on the extremes depicted in the
diagram. Information about what goes in (inputs to the production process) and
what comes out (outputs of the production process) allows comparison of input-
tions that produce similar things. If an organization
tion, the former
tions that produce different
amounts of output, we need to make judgements about whether there are
economies of scale which, in turn, relies on understanding the gold standard
tions can then be judged in terms of their relative
Specification choices (in parametric analysis of hospital
We concentrate on specifications choices to be made in the context of the
ital cost functions and the Stochastic Frontier
Analysis (SFA) as these will be used in the EuroDRG project. Similar choices also have
to be made in the context of the Data Envelopment Analysis (DEA). However, as the
only briefly introduce the DEA in very
general terms in section 3 of the appendix and for the complexities of specification
.
One of the first choices researchers face is the form in which they incorporate
variables in their model. Using variables in their natural units implies the assumption
that the explanatory variables are related linearly to the dependent variable (Jacobs
hange in costs as the
scale of activity changes. This assumption may not hold in practice as decreasing
returns to scale or increasing returns to scale or scope can imply variable marginal
way to model non-
linear relationships. In this case, the interpretations of coefficients changes from
Determinants of hospital costs and performance variation
natural units to percentage changes or elasticities. Other functional forms such as
including higher–order powers of explanatory variables can also be app
appropriateness can be scrutin
2.2 Total vs. average cost function
The choice between estimating average and total cost functions depends to a large
extent on the purpose and focus of the analysis. Conceptually economic
suggest that organizations can change their output or cost level in two ways: a) by
making proportionate changes to the amount of all inputs used in the production
process and b) by changing the composition of the input mix.
The effect of changing input composition depends on the scale properties of the
function (also called the degree of homogeneity). If the function is homogeneous of
degree 1, i.e. linearly homogenous, a proportionate change in use of input leads to a
change of output by the same
to scale, an average and a total cost function yield equivalent results
2006: 45).
From a statistical point of view estimating an average function is preferable if the
data being analysed are subject to heteroscedasticity, i.e. if the variance o
residual is not constant. The latter can be reduced by using an average cost function
for the model or by estimating the ratio of output or cost to a deflating variable,
where the residual is more likely to display homoscedasticity
disadvantage of using the ratio of output or cost to deflating variable is that there no
statistical criteria to guide the selection of the deflating variable. One option is to
making the dependent variable an average cost per unit of size. However, this
approach is only appropriate in the case of constant returns to scale. Alternatively,
one can deflate on an outp
the output for deflation substantially affects the estimates.
Before deflating a total cost function one should test for heteroscedasticity because
the error term is transformed by deflation
bias may be entered by deflation if the variable used for deflation is multicollinear
with one of the explanatory variables
eterminants of hospital costs and performance variation
natural units to percentage changes or elasticities. Other functional forms such as
order powers of explanatory variables can also be app
appropriateness can be scrutinized by applying a t-test.
Total vs. average cost function
The choice between estimating average and total cost functions depends to a large
extent on the purpose and focus of the analysis. Conceptually economic
tions can change their output or cost level in two ways: a) by
making proportionate changes to the amount of all inputs used in the production
process and b) by changing the composition of the input mix.
input composition depends on the scale properties of the
function (also called the degree of homogeneity). If the function is homogeneous of
degree 1, i.e. linearly homogenous, a proportionate change in use of input leads to a
change of output by the same proportion. Under this condition of constant returns
to scale, an average and a total cost function yield equivalent results
From a statistical point of view estimating an average function is preferable if the
data being analysed are subject to heteroscedasticity, i.e. if the variance o
residual is not constant. The latter can be reduced by using an average cost function
for the model or by estimating the ratio of output or cost to a deflating variable,
where the residual is more likely to display homoscedasticity (Intriligator 1978)
disadvantage of using the ratio of output or cost to deflating variable is that there no
o guide the selection of the deflating variable. One option is to
making the dependent variable an average cost per unit of size. However, this
approach is only appropriate in the case of constant returns to scale. Alternatively,
one can deflate on an output – but in the context of multiple outputs the choice of
the output for deflation substantially affects the estimates.
Before deflating a total cost function one should test for heteroscedasticity because
the error term is transformed by deflation (Kuh and Meyer 1955). In addition, new
may be entered by deflation if the variable used for deflation is multicollinear
with one of the explanatory variables (Kuh and Meyer 1955). Total cost functions
24
natural units to percentage changes or elasticities. Other functional forms such as
order powers of explanatory variables can also be applied. Their
The choice between estimating average and total cost functions depends to a large
extent on the purpose and focus of the analysis. Conceptually economic models
tions can change their output or cost level in two ways: a) by
making proportionate changes to the amount of all inputs used in the production
input composition depends on the scale properties of the
function (also called the degree of homogeneity). If the function is homogeneous of
degree 1, i.e. linearly homogenous, a proportionate change in use of input leads to a
proportion. Under this condition of constant returns
to scale, an average and a total cost function yield equivalent results (Jacobs et al.
From a statistical point of view estimating an average function is preferable if the
data being analysed are subject to heteroscedasticity, i.e. if the variance of the
residual is not constant. The latter can be reduced by using an average cost function
for the model or by estimating the ratio of output or cost to a deflating variable,
(Intriligator 1978). The
disadvantage of using the ratio of output or cost to deflating variable is that there no
o guide the selection of the deflating variable. One option is to
making the dependent variable an average cost per unit of size. However, this
approach is only appropriate in the case of constant returns to scale. Alternatively,
but in the context of multiple outputs the choice of
Before deflating a total cost function one should test for heteroscedasticity because
. In addition, new
may be entered by deflation if the variable used for deflation is multicollinear
. Total cost functions
Determinants of hospital costs and performance variation
have the advantage of incorporating various types of output. Other approaches to
deal with heteroscedasticity than estimating an ave
are estimating a logarithmic function
(White 1980).
2.3 Functional form
Various authors showed that the choice of the fu
cost function substantially affects the results of hospital cost or performance analysis
(Folland and Hofler 2001; Rosko and Mutter 2008; Smet 2002; Street 2003)
most common functional forms in parametric analyses are ad
specifications, which in principal are informed by neo
accept assumptions to very different degrees. We will briefly outline the main
features and implications of these in the following paragraphs.
(1) The most basic functional form are
variations in costs per unit of output among hospitals. As indicators for output these
early studies used mainly cost per case or cost per patient and as explanatory
variables they included “fairly indiscriminately
relationship to hospital costs is hypothesized and data are available”
The underlying explanatory model assumes that the cost determinants are linear and
additively separable and are specified in an additive
assumptions may not hold in practice. The additive
imply that an additional bed in the hospital raises costs by a fixed amount
independent of other factors such as hospital’s utilization, the spectrum of illnesses
treatment or wage levels in
The main advantage of this rather bold approach is that it can deal with the multi
product nature of hospitals, while keeping the number of variables manageable
(Smet 2002). However, this strength comes at a cost
between patient, organizational and or environmental variables ca
accounted for and therefore estimates suffer from limited explanatory scope and
power. While this form of hospital cost functions had considerable impact on public
policy in the US and in the UK during the 1980s
recently concentrate on more fl
eterminants of hospital costs and performance variation
have the advantage of incorporating various types of output. Other approaches to
deal with heteroscedasticity than estimating an average cost function in this context
are estimating a logarithmic function (Maddala 1988) or using a robust estimator
Functional form
Various authors showed that the choice of the functional form of the production or
cost function substantially affects the results of hospital cost or performance analysis
(Folland and Hofler 2001; Rosko and Mutter 2008; Smet 2002; Street 2003)
most common functional forms in parametric analyses are ad-hoc specifications and
specifications, which in principal are informed by neo-classical propositions but
accept assumptions to very different degrees. We will briefly outline the main
features and implications of these in the following paragraphs.
(1) The most basic functional form are ad-hoc specifications, which intend to explain
variations in costs per unit of output among hospitals. As indicators for output these
early studies used mainly cost per case or cost per patient and as explanatory
variables they included “fairly indiscriminately all variables for which a causal
relationship to hospital costs is hypothesized and data are available”
The underlying explanatory model assumes that the cost determinants are linear and
additively separable and are specified in an additive-linear functional form. These
t hold in practice. The additive-linear model for example would
imply that an additional bed in the hospital raises costs by a fixed amount
independent of other factors such as hospital’s utilization, the spectrum of illnesses
treatment or wage levels in the hospital.
The main advantage of this rather bold approach is that it can deal with the multi
product nature of hospitals, while keeping the number of variables manageable
. However, this strength comes at a cost – non-separable relationships
between patient, organizational and or environmental variables ca
accounted for and therefore estimates suffer from limited explanatory scope and
power. While this form of hospital cost functions had considerable impact on public
policy in the US and in the UK during the 1980s (Street 2003), most researchers
recently concentrate on more flexible models.
25
have the advantage of incorporating various types of output. Other approaches to
rage cost function in this context
or using a robust estimator
nctional form of the production or
cost function substantially affects the results of hospital cost or performance analysis
(Folland and Hofler 2001; Rosko and Mutter 2008; Smet 2002; Street 2003). The two
hoc specifications and
classical propositions but
accept assumptions to very different degrees. We will briefly outline the main
specifications, which intend to explain
variations in costs per unit of output among hospitals. As indicators for output these
early studies used mainly cost per case or cost per patient and as explanatory
all variables for which a causal
relationship to hospital costs is hypothesized and data are available” (Breyer 1987).
The underlying explanatory model assumes that the cost determinants are linear and
linear functional form. These
linear model for example would
imply that an additional bed in the hospital raises costs by a fixed amount –
independent of other factors such as hospital’s utilization, the spectrum of illnesses
The main advantage of this rather bold approach is that it can deal with the multi-
product nature of hospitals, while keeping the number of variables manageable
separable relationships
between patient, organizational and or environmental variables cannot be
accounted for and therefore estimates suffer from limited explanatory scope and
power. While this form of hospital cost functions had considerable impact on public
, most researchers
Determinants of hospital costs and performance variation
(2) The second group –
researchers to investigate the variance of output following changes in the level or
mix of inputs. Independent variables in this framework are inputs under the c
of hospital managers. Within this group different approaches can be identified which
accept various sets of restrictions with different implications. One can distinguish
between (2a) closed functional form, (2b) flexible functional form and (2c) hyb
flexible functional form cost functions.
(2a) Closed functional form cost functions accept a large set of common but rather
restrictive assumption used in neo
Cowing et al. 1983). These models, which we called “technological” cost functions in
the first part of the review, build on the insights of duality theory
suggesting a one-to-one correspondence between production und cost function
(Breyer 1987) and also implying a cost function which is non
homogeneous of degree one in factor prices
the well-known Cobb-Douglas logarithmic form:
where:
= total output
= technology
= labour
= capital
and positive parameters
The logarithmic form allows these parameters to be interpreted as elasticities. This
approach entails relatively high risks of misspecification, since researchers often feel
that they can hardly specify the true cost function. Moreover, the strict version
this approach requires that only factor input prices and quantities are incorporated
as explanatory variables. The influence of structural variables such as market
characteristics, and patient characteristics cannot be scrutinized. Hence, the
eterminants of hospital costs and performance variation
approaches following neoclassical proposition
researchers to investigate the variance of output following changes in the level or
mix of inputs. Independent variables in this framework are inputs under the c
of hospital managers. Within this group different approaches can be identified which
accept various sets of restrictions with different implications. One can distinguish
between (2a) closed functional form, (2b) flexible functional form and (2c) hyb
flexible functional form cost functions.
(2a) Closed functional form cost functions accept a large set of common but rather
restrictive assumption used in neo-classical economics (Conrad and Strauss 1983;
. These models, which we called “technological” cost functions in
the first part of the review, build on the insights of duality theory (Shepard 1970)
one correspondence between production und cost function
and also implying a cost function which is non-decreasing and
homogeneous of degree one in factor prices (Caves et al. 1980). A common form is
Douglas logarithmic form:
/ln �
positive parameters
The logarithmic form allows these parameters to be interpreted as elasticities. This
approach entails relatively high risks of misspecification, since researchers often feel
that they can hardly specify the true cost function. Moreover, the strict version
this approach requires that only factor input prices and quantities are incorporated
as explanatory variables. The influence of structural variables such as market
characteristics, and patient characteristics cannot be scrutinized. Hence, the
26
approaches following neoclassical proposition – enable
researchers to investigate the variance of output following changes in the level or
mix of inputs. Independent variables in this framework are inputs under the control
of hospital managers. Within this group different approaches can be identified which
accept various sets of restrictions with different implications. One can distinguish
between (2a) closed functional form, (2b) flexible functional form and (2c) hybrid
(2a) Closed functional form cost functions accept a large set of common but rather
(Conrad and Strauss 1983;
. These models, which we called “technological” cost functions in
(Shepard 1970)
one correspondence between production und cost function
decreasing and
. A common form is
(1)
The logarithmic form allows these parameters to be interpreted as elasticities. This
approach entails relatively high risks of misspecification, since researchers often feel
that they can hardly specify the true cost function. Moreover, the strict version of
this approach requires that only factor input prices and quantities are incorporated
as explanatory variables. The influence of structural variables such as market
characteristics, and patient characteristics cannot be scrutinized. Hence, the
Determinants of hospital costs and performance variation
estimates may be biased given that the underlying model disregards exogenous
factors (Breyer 1987). Consequently, this group of hospital cost functions is hardly
able to derive meaningful insight about potential
(2b) To circumvent these problems and to avoid
forms, which try to approximate the true functional form using techniques such as
local second-order Taylor approximation,
main problems of both the ad
circumvented, i.e. the deterministic approach
variables in the model. Most common variants of flexible functional forms are the
quadratic, the transcendental (translog) and the generalized transcendental
functional form. However, these models face other difficultie
form they can no longer handle large number of outputs such as different cases or
patients categories (Smet 2002)
functions in this group can handle generates additional drawbacks. Calculating
economies of scope and scale, i.e. deriving inputs abo
output levels increase or returns from specialization require that the function is
scrutinized at the level of (multiple) outputs and not in the neighbourhood of
approximations. Moreover, to estimate economies of scope and sc
about incremental costs is required. Since flexible functional form specifications
need to reduce the number of outputs in the model, they often operate on the basis
of some aggregate measure of output such as average or total costs. Since
and total cost functions fail to provide information about incremental costs and costs
at zero output level respectively, their use precludes analyzing issues such as
economies of scale and scope.
(2c) Hybrid functional form hospital cost function
assumptions, while still operating within the neoclassical framework. For example
using hybrid functional forms allows supplementing factors of production as
explanatory variables by other variables representing organizat
Hence, the impact of other exogenous
be scrutinized, while the basic assumption of homogeneity in factor prices is
eterminants of hospital costs and performance variation
may be biased given that the underlying model disregards exogenous
. Consequently, this group of hospital cost functions is hardly
able to derive meaningful insight about potential “legitimate” hospital cost variation.
(2b) To circumvent these problems and to avoid misspecification, flexible functional
forms, which try to approximate the true functional form using techniques such as
order Taylor approximation, were developed (Smet 2002)
main problems of both the ad-hoc and the strict neoclassical approaches are
circumvented, i.e. the deterministic approach towards the relationship between the
variables in the model. Most common variants of flexible functional forms are the
quadratic, the transcendental (translog) and the generalized transcendental
However, these models face other difficulties: due to their technical
form they can no longer handle large number of outputs such as different cases or
(Smet 2002). Moreover, the limited range of outputs that cost
functions in this group can handle generates additional drawbacks. Calculating
economies of scope and scale, i.e. deriving inputs about decreasing marginal cost as
output levels increase or returns from specialization require that the function is
scrutinized at the level of (multiple) outputs and not in the neighbourhood of
approximations. Moreover, to estimate economies of scope and scale information
about incremental costs is required. Since flexible functional form specifications
need to reduce the number of outputs in the model, they often operate on the basis
of some aggregate measure of output such as average or total costs. Since
and total cost functions fail to provide information about incremental costs and costs
at zero output level respectively, their use precludes analyzing issues such as
economies of scale and scope.
(2c) Hybrid functional form hospital cost functions allow relaxing some neoclassical
assumptions, while still operating within the neoclassical framework. For example
using hybrid functional forms allows supplementing factors of production as
explanatory variables by other variables representing organizational constrains.
Hence, the impact of other exogenous factors on performance and cost
be scrutinized, while the basic assumption of homogeneity in factor prices is
27
may be biased given that the underlying model disregards exogenous
. Consequently, this group of hospital cost functions is hardly
hospital cost variation.
misspecification, flexible functional
forms, which try to approximate the true functional form using techniques such as
(Smet 2002). Thereby the
and the strict neoclassical approaches are
towards the relationship between the
variables in the model. Most common variants of flexible functional forms are the
quadratic, the transcendental (translog) and the generalized transcendental
s: due to their technical
form they can no longer handle large number of outputs such as different cases or
. Moreover, the limited range of outputs that cost
functions in this group can handle generates additional drawbacks. Calculating
ut decreasing marginal cost as
output levels increase or returns from specialization require that the function is
scrutinized at the level of (multiple) outputs and not in the neighbourhood of
ale information
about incremental costs is required. Since flexible functional form specifications
need to reduce the number of outputs in the model, they often operate on the basis
of some aggregate measure of output such as average or total costs. Since average
and total cost functions fail to provide information about incremental costs and costs
at zero output level respectively, their use precludes analyzing issues such as
s allow relaxing some neoclassical
assumptions, while still operating within the neoclassical framework. For example
using hybrid functional forms allows supplementing factors of production as
ional constrains.
on performance and cost variation can
be scrutinized, while the basic assumption of homogeneity in factor prices is
Determinants of hospital costs and performance variation
maintained. These variables are not interpreted as contributing to the cost
minimum, but rather explain deviations of observed costs from cost minimization.
Overall, we face an ambiguous trade
functional form and less restrictive assumptions with regard to nature of
organizational and market characteristics or to focus on the ability of the model to
account for the multi-product nature of hospitals. Increasingly
and closed functional forms are being considered of limited value due to restrictive
assumptions and over simplistic specification. Flexible functional and hybrid forms
represent the majority of recent applications
Street 2003).
Vignettes or episode approach such as used in the EuroDRG project constitute a
third option that captures the benefits of flexible functional forms while not
suffering from artificially ignoring the multi
2.4 Input variables
Most parametric analysis of hospital costs build explicitly or implicitly on a neo
classical model of the production process. In this framework factor markets are
assumed to be competitive and free from monistic pressures
hospital managers face given prices and can solely decide on the mix
scale of input use and their application in the production process.
for inputs, however, are
researchers often simply omit input prices in their models. This appr
assumption that input prices are identical across hospitals included in the sample or
that the substitution rate for hospital technology is zero
consequence, insights about the effects of differences in input prices
different wage levels, capital costs or differences in the cost of medical technology
across hospitals, cannot be generated. Moreover, as we saw earlier the application
of the strict neoclassical model implies that the hospital cost function is homothetic.
Given the high degree of restrictiveness of these assumptions, recent analyses often
relaxed the former and incorporated input prices in the model in the framework of
more flexible functional forms.
eterminants of hospital costs and performance variation
maintained. These variables are not interpreted as contributing to the cost
inimum, but rather explain deviations of observed costs from cost minimization.
Overall, we face an ambiguous trade-off: either to prioritize flexibility of the
functional form and less restrictive assumptions with regard to nature of
rket characteristics or to focus on the ability of the model to
product nature of hospitals. Increasingly, ad hoc specifications
closed functional forms are being considered of limited value due to restrictive
simplistic specification. Flexible functional and hybrid forms
represent the majority of recent applications (Rosko and Mutter 2008; Smet 2002;
Vignettes or episode approach such as used in the EuroDRG project constitute a
third option that captures the benefits of flexible functional forms while not
suffering from artificially ignoring the multi-product nature of hospitals.
parametric analysis of hospital costs build explicitly or implicitly on a neo
classical model of the production process. In this framework factor markets are
assumed to be competitive and free from monistic pressures (Smet 2002)
hospital managers face given prices and can solely decide on the mix
scale of input use and their application in the production process. Reliable price data
often hard to collect or simply not available. Therefore
researchers often simply omit input prices in their models. This approach implies the
assumption that input prices are identical across hospitals included in the sample or
that the substitution rate for hospital technology is zero (Cowing et al. 1983)
insights about the effects of differences in input prices
different wage levels, capital costs or differences in the cost of medical technology
cannot be generated. Moreover, as we saw earlier the application
neoclassical model implies that the hospital cost function is homothetic.
Given the high degree of restrictiveness of these assumptions, recent analyses often
relaxed the former and incorporated input prices in the model in the framework of
functional forms.
28
maintained. These variables are not interpreted as contributing to the cost
inimum, but rather explain deviations of observed costs from cost minimization.
off: either to prioritize flexibility of the
functional form and less restrictive assumptions with regard to nature of
rket characteristics or to focus on the ability of the model to
ad hoc specifications
closed functional forms are being considered of limited value due to restrictive
simplistic specification. Flexible functional and hybrid forms
(Rosko and Mutter 2008; Smet 2002;
Vignettes or episode approach such as used in the EuroDRG project constitute a
third option that captures the benefits of flexible functional forms while not
product nature of hospitals.
parametric analysis of hospital costs build explicitly or implicitly on a neo-
classical model of the production process. In this framework factor markets are
(Smet 2002). Hence,
hospital managers face given prices and can solely decide on the mix of inputs, the
eliable price data
hard to collect or simply not available. Therefore,
oach implies the
assumption that input prices are identical across hospitals included in the sample or
(Cowing et al. 1983). As a
insights about the effects of differences in input prices, such as
different wage levels, capital costs or differences in the cost of medical technology
cannot be generated. Moreover, as we saw earlier the application
neoclassical model implies that the hospital cost function is homothetic.
Given the high degree of restrictiveness of these assumptions, recent analyses often
relaxed the former and incorporated input prices in the model in the framework of
Determinants of hospital costs and performance variation
Another central issue when considering the input side is, how inputs are
disaggregated (Jacobs et al. 2006)
level of disaggregation: some studies use aggregate costs, while others try to
disaggregate all relevant inputs. This variation of practice reflects on the o
differences in the availability of data for input prices and quantities.
hand, choices with regard to the level of disaggregation also co
of the analysis. Using total costs as the single measure of inputs implies th
assumption that hospitals can deploy inputs freely without external constrains. This
approach hence takes a long term perspective, assuming that hospitals can adopt an
optimal mix of capital and labour. Disaggregation comes at the cost that models
become less parsimonious, which captures some of the explanatory power of those
factors in the production for which weighting is less clear
Commonly disaggregated inputs are labour and capital. An important additional
aspect is to account for services that hospitals have outso
2.5 Outputs
As the model of the production process is the starting point of all analyses of
hospital costs good measures for output are essential. Nevertheless, it is well known
that defining outputs is problematic in the health sector
demanded for its own sake but rather due to its positive contribution to health
status. Given this background
of health outcomes. However, health outcomes are hard to measure and rarely
systematically collected by hospitals. Researchers therefore tend to use activity
indicators such as the number of cases treate
organization or the number of procedures performed as approximations for output.
Using these indicators suffers from various limitations:
(1) Firstly, hospitals generating better health outcomes with less activity, for
example by developing smart medical pathways are penalized. However, the
quality of the services is hard to measure and therefore hard to incorporate in
production or cost functions
(2) Secondly, given the multi
weight of each output has to be sp
eterminants of hospital costs and performance variation
Another central issue when considering the input side is, how inputs are
(Jacobs et al. 2006). Studies vary to a great extent with regard to the
level of disaggregation: some studies use aggregate costs, while others try to
disaggregate all relevant inputs. This variation of practice reflects on the o
differences in the availability of data for input prices and quantities.
, choices with regard to the level of disaggregation also co-determine the focus
of the analysis. Using total costs as the single measure of inputs implies th
assumption that hospitals can deploy inputs freely without external constrains. This
approach hence takes a long term perspective, assuming that hospitals can adopt an
optimal mix of capital and labour. Disaggregation comes at the cost that models
less parsimonious, which captures some of the explanatory power of those
factors in the production for which weighting is less clear (Jacobs et al. 2006: 30)
Commonly disaggregated inputs are labour and capital. An important additional
aspect is to account for services that hospitals have outsourced.
As the model of the production process is the starting point of all analyses of
hospital costs good measures for output are essential. Nevertheless, it is well known
outputs is problematic in the health sector, as health care
demanded for its own sake but rather due to its positive contribution to health
status. Given this background, hospital output should ideally be measured in terms
of health outcomes. However, health outcomes are hard to measure and rarely
systematically collected by hospitals. Researchers therefore tend to use activity
indicators such as the number of cases treated, the number of hospital days per
organization or the number of procedures performed as approximations for output.
Using these indicators suffers from various limitations:
Firstly, hospitals generating better health outcomes with less activity, for
e by developing smart medical pathways are penalized. However, the
quality of the services is hard to measure and therefore hard to incorporate in
production or cost functions (Jacobs et al. 2006: 28).
Secondly, given the multi-product nature of hospitals, the relative value or
weight of each output has to be specified.
29
Another central issue when considering the input side is, how inputs are
. Studies vary to a great extent with regard to the
level of disaggregation: some studies use aggregate costs, while others try to
disaggregate all relevant inputs. This variation of practice reflects on the one hand
differences in the availability of data for input prices and quantities. On the other
determine the focus
of the analysis. Using total costs as the single measure of inputs implies the
assumption that hospitals can deploy inputs freely without external constrains. This
approach hence takes a long term perspective, assuming that hospitals can adopt an
optimal mix of capital and labour. Disaggregation comes at the cost that models
less parsimonious, which captures some of the explanatory power of those
(Jacobs et al. 2006: 30).
Commonly disaggregated inputs are labour and capital. An important additional
As the model of the production process is the starting point of all analyses of
hospital costs good measures for output are essential. Nevertheless, it is well known
as health care is rarely
demanded for its own sake but rather due to its positive contribution to health
hospital output should ideally be measured in terms
of health outcomes. However, health outcomes are hard to measure and rarely
systematically collected by hospitals. Researchers therefore tend to use activity
d, the number of hospital days per
organization or the number of procedures performed as approximations for output.
Firstly, hospitals generating better health outcomes with less activity, for
e by developing smart medical pathways are penalized. However, the
quality of the services is hard to measure and therefore hard to incorporate in
product nature of hospitals, the relative value or
Determinants of hospital costs and performance variation
As we will see below in the sub
implicitly assume that the expenditure allocation within the hospital reflects societal
values of different outputs, which might be questionable. Moreover, in t
classical production framework the level of output should be completely beyond the
control of the hospital managers and physicians, i.e. exogenous. This assumption has
been challenged from two angles:
(1) Firstly, it has been argued that hospital manag
side by producing more if their hospital is characterized by a favourable cost
structure or less if the opposite is the case.
(2) Secondly, many studies argue that physicians may induce demand, operating
exogenous to the deci
In both cases, estimates generated by a model that does not account for the former
are biased. Nevertheless, exogenous determination of levels of output is often
assumed given that case payment systems and the cost containmen
third-party payers weakened the relationship between gross
quantity demanded (Smet 2002)
models to determine hospital performance or sources of cost variation is that they
incorporate well-designed measures of output and that they are
for output being determined (partially) within hospitals via econometric techniques
such as instrumental variables
2.6 Environmental variables
Any analysis of hospital costs needs to clarify how it approaches factors that
constrain the production of health care. There is often considerable deb
what factors should be considered constraints. In the short run, many factors are
outside the control of the organ
of variation. In the long-term a broader set of factors is potentially under t
of the organizations, but the extent and nature of this control will vary depending on
the nature of the context.
Therefore the assumptions with regard to the equilibrium condition, i.e. the state
(long- vs. short-term) in which managers can de
eterminants of hospital costs and performance variation
As we will see below in the sub-section on weights (2.7), parametric analyses tend to
implicitly assume that the expenditure allocation within the hospital reflects societal
values of different outputs, which might be questionable. Moreover, in t
classical production framework the level of output should be completely beyond the
control of the hospital managers and physicians, i.e. exogenous. This assumption has
been challenged from two angles:
Firstly, it has been argued that hospital managers may manipulate the supply
side by producing more if their hospital is characterized by a favourable cost
structure or less if the opposite is the case.
Secondly, many studies argue that physicians may induce demand, operating
exogenous to the decisions of hospital management.
estimates generated by a model that does not account for the former
are biased. Nevertheless, exogenous determination of levels of output is often
assumed given that case payment systems and the cost containmen
party payers weakened the relationship between gross-price charged and the
(Smet 2002). Still, one of the defining features of well
models to determine hospital performance or sources of cost variation is that they
designed measures of output and that they are capable to account
for output being determined (partially) within hospitals via econometric techniques
such as instrumental variables (Smet 2002).
Environmental variables
Any analysis of hospital costs needs to clarify how it approaches factors that
constrain the production of health care. There is often considerable deb
what factors should be considered constraints. In the short run, many factors are
outside the control of the organizations and could be considered “legitimate
term a broader set of factors is potentially under t
tions, but the extent and nature of this control will vary depending on
the nature of the context.
Therefore the assumptions with regard to the equilibrium condition, i.e. the state
term) in which managers can determine the level of all inputs, are
30
section on weights (2.7), parametric analyses tend to
implicitly assume that the expenditure allocation within the hospital reflects societal
values of different outputs, which might be questionable. Moreover, in the neo-
classical production framework the level of output should be completely beyond the
control of the hospital managers and physicians, i.e. exogenous. This assumption has
ers may manipulate the supply
side by producing more if their hospital is characterized by a favourable cost
Secondly, many studies argue that physicians may induce demand, operating
estimates generated by a model that does not account for the former
are biased. Nevertheless, exogenous determination of levels of output is often
assumed given that case payment systems and the cost containment pressure by
price charged and the
. Still, one of the defining features of well-suited
models to determine hospital performance or sources of cost variation is that they
capable to account
for output being determined (partially) within hospitals via econometric techniques
Any analysis of hospital costs needs to clarify how it approaches factors that
constrain the production of health care. There is often considerable debate as to
what factors should be considered constraints. In the short run, many factors are
legitimate” factors
term a broader set of factors is potentially under the control
tions, but the extent and nature of this control will vary depending on
Therefore the assumptions with regard to the equilibrium condition, i.e. the state
termine the level of all inputs, are
Determinants of hospital costs and performance variation
important. Some authors assume that hospital managers are essentially able to set
all inputs at the cost-minimizing level, include a price for capital and therefore
estimate a long-run cost function. Others argue that o
be employed at the cost-
(Smet 2002).
Econometric techniques offer some orientation by providing tools to test whether
hospitals operate in short or long run equilibrium using the so
condition (Braeutigam and Daughety 1983)
performed with reliable and detailed data for inputs, which are often not available.
Estimating a long-run hospital cost function without testing the appropriateness of
the long-term equilibrium assumption may lead to bia
misspecification of functional form. Most researchers therefore agree that in the
absence of high quality measures of capital input, short
should be estimated (Cowing et al. 1983; Smet 2002; Vita 1990)
Having agreed on the priority given to short
to incorporate those factors, which are beyond the control of hospital mangers in
the analysis. In the framework of the parametric analyses there are three main ways
to account for environmental variables:
- Firstly, comparisons can be restricted to hospitals operating within similarly
constrained environments
- Secondly, external constrains can be included directly as explanatory
variables in the production model.
- Thirdly, risk adjustment techniques adjust organizational output for
differences in cons
(Jacobs et al. 2006: 35)
this approach is often considered superior to the other approaches, since it
adjusts each output only for those constrains that apply specifically rather
than adjusting all outputs generally for external constrains.
Risk adjustment to account for the fact that output is heterogeneous with regard to
certain dimensions is often operational
eterminants of hospital costs and performance variation
important. Some authors assume that hospital managers are essentially able to set
minimizing level, include a price for capital and therefore
run cost function. Others argue that only easily adjustable inputs can
-minimization level and estimate short run cost functions
Econometric techniques offer some orientation by providing tools to test whether
hospitals operate in short or long run equilibrium using the so-called envelope
(Braeutigam and Daughety 1983). The latter, however, can only be
performed with reliable and detailed data for inputs, which are often not available.
run hospital cost function without testing the appropriateness of
term equilibrium assumption may lead to biased estimates and
misspecification of functional form. Most researchers therefore agree that in the
absence of high quality measures of capital input, short-run hospital cost functions
(Cowing et al. 1983; Smet 2002; Vita 1990).
Having agreed on the priority given to short-run models, one needs to consider how
to incorporate those factors, which are beyond the control of hospital mangers in
ework of the parametric analyses there are three main ways
to account for environmental variables:
Firstly, comparisons can be restricted to hospitals operating within similarly
constrained environments (Everitt et al. 2001).
Secondly, external constrains can be included directly as explanatory
variables in the production model.
risk adjustment techniques adjust organizational output for
differences in constrains before they are deployed in the efficiency model
(Jacobs et al. 2006: 35). In the light of the multi-product nature of hospitals
this approach is often considered superior to the other approaches, since it
adjusts each output only for those constrains that apply specifically rather
justing all outputs generally for external constrains.
Risk adjustment to account for the fact that output is heterogeneous with regard to
certain dimensions is often operationalized via product mix descriptor variables,
31
important. Some authors assume that hospital managers are essentially able to set
minimizing level, include a price for capital and therefore
nly easily adjustable inputs can
minimization level and estimate short run cost functions
Econometric techniques offer some orientation by providing tools to test whether
called envelope
. The latter, however, can only be
performed with reliable and detailed data for inputs, which are often not available.
run hospital cost function without testing the appropriateness of
sed estimates and
misspecification of functional form. Most researchers therefore agree that in the
run hospital cost functions
run models, one needs to consider how
to incorporate those factors, which are beyond the control of hospital mangers in
ework of the parametric analyses there are three main ways
Firstly, comparisons can be restricted to hospitals operating within similarly
Secondly, external constrains can be included directly as explanatory
risk adjustment techniques adjust organizational output for
trains before they are deployed in the efficiency model
product nature of hospitals
this approach is often considered superior to the other approaches, since it
adjusts each output only for those constrains that apply specifically rather
Risk adjustment to account for the fact that output is heterogeneous with regard to
d via product mix descriptor variables,
Determinants of hospital costs and performance variation
which can be grouped into three broad categories: (1) case
quality, and (3) intra-diagnosis related group severity of illness
2008). While contributing to avoid specification bias, the use of product descriptor
variables has three additional global effects, which need to be taken into account.
Firstly, the addition of further explanatory variables is always likely to
decline of the previously unexplained residual and thereby to reduce estimated
average inefficiency or cost variation
parsimony and adds uncertainty with regard to the results. Finally, the data
requirements for risk adjustment are demanding and some controversy exists about
appropriate techniques (Jacobs et al. 2006: 36)
2.7 Weights
A key aspect, which policy makers need to consider when scrutinizing cost and
output variation across individual or groups of organizations, is whether all
organizations are meant to fulfil the same task and objectives
2005). Ideally, any analysis that
to clarify the underlying assumptions with regard to the relative value it allocates to
different outputs and the way specific outputs are therefore included and weighted
in the model (Smith and Street 2005)
Clearly, in the context of the multi
complex. Various approaches have been used to account for this complexity such as
creating a single index of outputs, estimation of a cost rather than a production
function or the use of distance f
Smith and Street (2005) point out that common to all approaches is that the weight
for each output is calculated via the sample mean cost of producing an additional
unit of output. This implies that weights are not allocated with reference to societal
values, but rather estimate
Street 2005). As a consequence most models implicitly assume that the expenditure
allocation decisions of managers and physicians within hospitals reflect the values
that society places on different outputs
models attach zero weight to any output that is not explicitly specified in the
production model. Hence any resources devoted to outputs, which do not enter the
eterminants of hospital costs and performance variation
which can be grouped into three broad categories: (1) case-mix complexity, (2)
diagnosis related group severity of illness (Rosko a
. While contributing to avoid specification bias, the use of product descriptor
variables has three additional global effects, which need to be taken into account.
Firstly, the addition of further explanatory variables is always likely to
decline of the previously unexplained residual and thereby to reduce estimated
average inefficiency or cost variation (Jacobs et al. 2006). However, it reduces
parsimony and adds uncertainty with regard to the results. Finally, the data
requirements for risk adjustment are demanding and some controversy exists about
(Jacobs et al. 2006: 36).
A key aspect, which policy makers need to consider when scrutinizing cost and
output variation across individual or groups of organizations, is whether all
organizations are meant to fulfil the same task and objectives (Smith and Street
. Ideally, any analysis that compares output or costs across organizations needs
to clarify the underlying assumptions with regard to the relative value it allocates to
different outputs and the way specific outputs are therefore included and weighted
(Smith and Street 2005).
xt of the multi-product hospital world, the former is very
complex. Various approaches have been used to account for this complexity such as
creating a single index of outputs, estimation of a cost rather than a production
function or the use of distance functions (Coelli and Perelman 2000; Shepard 1970)
point out that common to all approaches is that the weight
for each output is calculated via the sample mean cost of producing an additional
unit of output. This implies that weights are not allocated with reference to societal
values, but rather estimated as a by-product of statistical estimation
. As a consequence most models implicitly assume that the expenditure
allocation decisions of managers and physicians within hospitals reflect the values
that society places on different outputs (Smith and Street 2005). Moreover, all
attach zero weight to any output that is not explicitly specified in the
production model. Hence any resources devoted to outputs, which do not enter the
32
mix complexity, (2)
(Rosko and Mutter
. While contributing to avoid specification bias, the use of product descriptor
variables has three additional global effects, which need to be taken into account.
Firstly, the addition of further explanatory variables is always likely to lead to a
decline of the previously unexplained residual and thereby to reduce estimated
. However, it reduces
parsimony and adds uncertainty with regard to the results. Finally, the data
requirements for risk adjustment are demanding and some controversy exists about
A key aspect, which policy makers need to consider when scrutinizing cost and
output variation across individual or groups of organizations, is whether all
(Smith and Street
compares output or costs across organizations needs
to clarify the underlying assumptions with regard to the relative value it allocates to
different outputs and the way specific outputs are therefore included and weighted
product hospital world, the former is very
complex. Various approaches have been used to account for this complexity such as
creating a single index of outputs, estimation of a cost rather than a production
(Coelli and Perelman 2000; Shepard 1970).
point out that common to all approaches is that the weight
for each output is calculated via the sample mean cost of producing an additional
unit of output. This implies that weights are not allocated with reference to societal
product of statistical estimation (Smith and
. As a consequence most models implicitly assume that the expenditure
allocation decisions of managers and physicians within hospitals reflect the values
. Moreover, all
attach zero weight to any output that is not explicitly specified in the
production model. Hence any resources devoted to outputs, which do not enter the
Determinants of hospital costs and performance variation
model, are hypothesized to contribute to inefficiency or illegitimate cost variation.
Thirdly, assumptions with regard to the nature of the rate of return from additional
units of output, i.e. constant versus variable returns, considerably affect the weights
that are attached to different outputs.
2.8 Dynamic nature of production
Unsolved is the question how
process as current performance depends on past inheritances. Furthermore, hospital
managers also invest resources in future attainments
Adequate measures for organizational endowments are lacking. Given thes
limitations, estimating cost determinants or inefficiency scores by analysing panel
data might be a more suitable way to account for dynamic effects in the production
process (Bond 2002; Jacobs et al. 2006; Smith and Street 2005)
2.9 Modelling the error term
One of the fundamental innovations of the SFA is interpreting the residuals, i.e. the
difference between observed hospital costs or outputs and that predicted, as
comprising random error and inefficiency. These two components are as
distributed differently: for the random error term a normal distribution is assumed,
while the inefficiency part can take various distributional forms. However, for cross
sectional data no economic or statistical criteria are available to infor
the distributional characteristics of the inefficiency term
and Sickles 1984). Researchers are commonly provided with four distributions which
they can apply to the inefficiency error term: a half
exponential or a gamma distribution
generates different estimates of average inefficiency in the sample as a whole and of
relative inefficiency of individual hospitals
2008; Zuckerman et al. 1994)
distributions on relative and average inefficiency
Mutter 2008; Zuckerman et al. 1994)
comparing it to the difference resulting from decomposing inefficiency into two
components versus interpreting the entire residuals as inefficiency using COLS
(Jacobs et al. 2006: 57).
eterminants of hospital costs and performance variation
model, are hypothesized to contribute to inefficiency or illegitimate cost variation.
ions with regard to the nature of the rate of return from additional
units of output, i.e. constant versus variable returns, considerably affect the weights
that are attached to different outputs.
Dynamic nature of production
Unsolved is the question how to deal with the dynamic nature of the production
process as current performance depends on past inheritances. Furthermore, hospital
managers also invest resources in future attainments (Smith and Street 2005)
Adequate measures for organizational endowments are lacking. Given thes
limitations, estimating cost determinants or inefficiency scores by analysing panel
data might be a more suitable way to account for dynamic effects in the production
(Bond 2002; Jacobs et al. 2006; Smith and Street 2005).
odelling the error term
One of the fundamental innovations of the SFA is interpreting the residuals, i.e. the
difference between observed hospital costs or outputs and that predicted, as
comprising random error and inefficiency. These two components are as
distributed differently: for the random error term a normal distribution is assumed,
while the inefficiency part can take various distributional forms. However, for cross
sectional data no economic or statistical criteria are available to inform the choice of
the distributional characteristics of the inefficiency term (Newhouse 1994; Schmidt
. Researchers are commonly provided with four distributions which
they can apply to the inefficiency error term: a half-normal, a truncated
exponential or a gamma distribution (Greene 2004). The choice of the distribution
generates different estimates of average inefficiency in the sample as a whole and of
relative inefficiency of individual hospitals (Jacobs et al. 2006; Rosko and Mutter
2008; Zuckerman et al. 1994). Overall, the significance of the impact of different
distributions on relative and average inefficiency (Jacobs et al. 2006; Rosko and
Mutter 2008; Zuckerman et al. 1994) seems to be limited, especially when
it to the difference resulting from decomposing inefficiency into two
components versus interpreting the entire residuals as inefficiency using COLS
33
model, are hypothesized to contribute to inefficiency or illegitimate cost variation.
ions with regard to the nature of the rate of return from additional
units of output, i.e. constant versus variable returns, considerably affect the weights
to deal with the dynamic nature of the production
process as current performance depends on past inheritances. Furthermore, hospital
(Smith and Street 2005).
Adequate measures for organizational endowments are lacking. Given these
limitations, estimating cost determinants or inefficiency scores by analysing panel
data might be a more suitable way to account for dynamic effects in the production
One of the fundamental innovations of the SFA is interpreting the residuals, i.e. the
difference between observed hospital costs or outputs and that predicted, as
comprising random error and inefficiency. These two components are assumed to be
distributed differently: for the random error term a normal distribution is assumed,
while the inefficiency part can take various distributional forms. However, for cross-
m the choice of
use 1994; Schmidt
. Researchers are commonly provided with four distributions which
normal, a truncated-normal,
. The choice of the distribution
generates different estimates of average inefficiency in the sample as a whole and of
(Jacobs et al. 2006; Rosko and Mutter
. Overall, the significance of the impact of different
(Jacobs et al. 2006; Rosko and
seems to be limited, especially when
it to the difference resulting from decomposing inefficiency into two
components versus interpreting the entire residuals as inefficiency using COLS
Determinants of hospital costs and performance variation
2.10 One versus two stage estimation
Identifying correlate variables of inefficiency
variables is highly relevant for the identification of
performance variation. The analysis of the former can be conducted in one or two
stages (Rosko and Mutter 2008)
approaches in which inefficiency estimates are calculated in a first step and in a
second stage these estimates are regressed against a set of factors thought
correlate with inefficiency
estimate the stochastic frontier and the inefficiency model, which allows estimating
the effect of hospital specific and environm
Coelli 1995; Coelli et al. 2005; Hjalmarsson et al. 1996; Wang and Schmidt 2002)
Research indicates that two
and Rosenman 2001; Rosko and Mutter 2008; Wang and Schmidt 2002)
hence be interpreted with great caution and where possible ought to be checked
against results from one stage estimation.
3 Efficiency analysis
3.1 The main approaches to efficiency analysis: SFA and DEA
The two main techniques to measure relative efficiency are S
Analysis (SFA), which is a form of econometric model, and Data Envelopment
Analysis (DEA), which is a form of linear optim
each of these techniques briefly.
SFA is a special form of the standard economet
theory. The standard model takes the general form:
1
M
k m mk k
m
Y α β ε=
= + +∑ z
where k
Y is the total amount of output for each organ
constant and we have a set of
variables might measure the amount of labour or capital input used by each
organization or the constr
frontier. m
β captures the influence of a particular explanatory variable
eterminants of hospital costs and performance variation
One versus two stage estimation
tifying correlate variables of inefficiency such as firm-specific or environmental
riables is highly relevant for the identification of “legitimate” sources of hospital
performance variation. The analysis of the former can be conducted in one or two
(Rosko and Mutter 2008). The first generation of SFA studies use two
approaches in which inefficiency estimates are calculated in a first step and in a
second stage these estimates are regressed against a set of factors thought
correlate with inefficiency (Pitt and Lee 1981). One stage approaches simultaneously
estimate the stochastic frontier and the inefficiency model, which allows estimating
the effect of hospital specific and environmental variables directly
et al. 2005; Hjalmarsson et al. 1996; Wang and Schmidt 2002)
Research indicates that two-stage estimation leads to substantially biased results
and Rosenman 2001; Rosko and Mutter 2008; Wang and Schmidt 2002)
ce be interpreted with great caution and where possible ought to be checked
against results from one stage estimation.
Efficiency analysis
The main approaches to efficiency analysis: SFA and DEA
The two main techniques to measure relative efficiency are Stochastic Frontier
Analysis (SFA), which is a form of econometric model, and Data Envelopment
Analysis (DEA), which is a form of linear optimization. We introduce and compare
each of these techniques briefly.
SFA is a special form of the standard econometric model that builds on production
theory. The standard model takes the general form:
is the total amount of output for each organization k K=
constant and we have a set of 1...m M= explanatory variables m
z . These explanatory
variables might measure the amount of labour or capital input used by each
tion or the constraints faced by the organization in attaining the production
captures the influence of a particular explanatory variable
34
specific or environmental
sources of hospital
performance variation. The analysis of the former can be conducted in one or two
. The first generation of SFA studies use two-stage
approaches in which inefficiency estimates are calculated in a first step and in a
second stage these estimates are regressed against a set of factors thought to
. One stage approaches simultaneously
estimate the stochastic frontier and the inefficiency model, which allows estimating
ental variables directly (Battese and
et al. 2005; Hjalmarsson et al. 1996; Wang and Schmidt 2002).
stage estimation leads to substantially biased results (Li
and Rosenman 2001; Rosko and Mutter 2008; Wang and Schmidt 2002) and should
ce be interpreted with great caution and where possible ought to be checked
The main approaches to efficiency analysis: SFA and DEA
tochastic Frontier
Analysis (SFA), which is a form of econometric model, and Data Envelopment
tion. We introduce and compare
ric model that builds on production
(2)
1...k K= , α is a
. These explanatory
variables might measure the amount of labour or capital input used by each
tion in attaining the production
captures the influence of a particular explanatory variable m
z on
Determinants of hospital costs and performance variation
output. If m
β is positive, the explanatory va
The error term ε captures the imperfect relationship between these explanatory
variables (i.e. the model) and observed output.
SFA has been developed to address a fundamental measurement problem:
inefficiency is unobservable. How can one measure something that
lack of effort that an organ
problem in two stages.
First, it specifies the form and location of the production frontier. This involves
comparing different organ
organization(s) are doing best. This involves specifying a production model where
( )k mk
Y f= z . We shall consider this specification in more detail shortly.
Second, the production of the remaining organ
so that unobservable inefficiency is estimated by the distance from the frontier.
However, as we noted in equation (1), true (unobserved) performance is also
measured imperfectly, captured previously by the error term
of inefficiency, the term
SFA model disentangles these components, so that
inefficiency and v captures measurement or modelling error. The standar
equation, then, is re-specified as:
1
M
m m mk k k
m
Y u vα β=
= + + +∑ z
Figure 1 provides a graphical illustration of the process, taken from the World Health
Organization’s attempt the measure the relative performance of different countries
in producing health (World Health Organization, 2000)
Adjusted Life Expectancy (DALE) as the output of product
per capita as the input. Each dot represents a unit of observation
in this example. The SFA frontier runs through the cloud of observations but not
through the uppermost data points. Some points lie above the
measurement error v . For points below the frontier, the vertical distance comprises
a combination of inefficiency
eterminants of hospital costs and performance variation
is positive, the explanatory variable has a positive influence on output.
captures the imperfect relationship between these explanatory
variables (i.e. the model) and observed output.
has been developed to address a fundamental measurement problem:
inefficiency is unobservable. How can one measure something that is not there: the
that an organization ought to exert, for instance? SFA tries to solve this
First, it specifies the form and location of the production frontier. This involves
comparing different organizations producing the same things, to see which
are doing best. This involves specifying a production model where
. We shall consider this specification in more detail shortly.
Second, the production of the remaining organizations is compared to the frontier,
so that unobservable inefficiency is estimated by the distance from the frontier.
e noted in equation (1), true (unobserved) performance is also
measured imperfectly, captured previously by the error term ε . But in the context
ε captures both measurement error and inefficiency. The
SFA model disentangles these components, so that u vε = + , where
captures measurement or modelling error. The standar
specified as:
m m mk k kY u v
Figure 1 provides a graphical illustration of the process, taken from the World Health
tion’s attempt the measure the relative performance of different countries
(World Health Organization, 2000). Here we observe Disability
Adjusted Life Expectancy (DALE) as the output of production and health expenditure
per capita as the input. Each dot represents a unit of observation – each is a country
in this example. The SFA frontier runs through the cloud of observations but not
through the uppermost data points. Some points lie above the frontier because of
. For points below the frontier, the vertical distance comprises
a combination of inefficiency u and measurement error v .
35
riable has a positive influence on output.
captures the imperfect relationship between these explanatory
has been developed to address a fundamental measurement problem:
is not there: the
tion ought to exert, for instance? SFA tries to solve this
First, it specifies the form and location of the production frontier. This involves
tions producing the same things, to see which
are doing best. This involves specifying a production model where
. We shall consider this specification in more detail shortly.
tions is compared to the frontier,
so that unobservable inefficiency is estimated by the distance from the frontier.
e noted in equation (1), true (unobserved) performance is also
. But in the context
measurement error and inefficiency. The
, where u captures
captures measurement or modelling error. The standard
(3)
Figure 1 provides a graphical illustration of the process, taken from the World Health
tion’s attempt the measure the relative performance of different countries
. Here we observe Disability
ion and health expenditure
each is a country
in this example. The SFA frontier runs through the cloud of observations but not
frontier because of
. For points below the frontier, the vertical distance comprises
Determinants of hospital costs and performance variation
DEA derives from an engineering tradition that presumes accurate data, so does not
allow for measurement error. This greatly simplifies the produ
its most basic form, is specified as the ratio of output to input. This conforms to the
simple notion that an organ
the same amount of output can be considered more efficient. Tho
with the highest ratios of output to input are considered efficient, and the efficiency
frontier is constructed by joining these observations up in the input
The frontier thus comprises a series of linear segments connecting o
observation to another. Inefficient organ
frontier in DEA. The inefficiency of the organ
calculated relative to this
dataset as in Figure 1, but employing DEA instead of SFA. Thus, while careful
specification of the production model is required for SFA, when applying DEA the
location (and the shape) of the efficiency frontier is determined by the data.
Figure 1: An example of a stochastic frontier going through a cloud of observations
eterminants of hospital costs and performance variation
derives from an engineering tradition that presumes accurate data, so does not
allow for measurement error. This greatly simplifies the production model which, in
its most basic form, is specified as the ratio of output to input. This conforms to the
simple notion that an organization that employs less input than another to produce
the same amount of output can be considered more efficient. Those observations
with the highest ratios of output to input are considered efficient, and the efficiency
frontier is constructed by joining these observations up in the input
The frontier thus comprises a series of linear segments connecting o
observation to another. Inefficient organizations are “enveloped” by the efficiency
frontier in DEA. The inefficiency of the organizations within the frontier boundary is
calculated relative to this “envelope”, as can be seen in Figure 2, usin
dataset as in Figure 1, but employing DEA instead of SFA. Thus, while careful
specification of the production model is required for SFA, when applying DEA the
location (and the shape) of the efficiency frontier is determined by the data.
: An example of a stochastic frontier going through a cloud of observations
36
derives from an engineering tradition that presumes accurate data, so does not
ction model which, in
its most basic form, is specified as the ratio of output to input. This conforms to the
tion that employs less input than another to produce
se observations
with the highest ratios of output to input are considered efficient, and the efficiency
frontier is constructed by joining these observations up in the input-output space.
The frontier thus comprises a series of linear segments connecting one efficient
by the efficiency
tions within the frontier boundary is
, as can be seen in Figure 2, using the same
dataset as in Figure 1, but employing DEA instead of SFA. Thus, while careful
specification of the production model is required for SFA, when applying DEA the
location (and the shape) of the efficiency frontier is determined by the data.
: An example of a stochastic frontier going through a cloud of observations
Determinants of hospital costs and performance variation
DEA models can be run for both constant returns to scale (CRS) and a more flexible
variable returns to scale (VRS) (as shown in Figure 2) which
when not all organizations can be considered to be operating at an optimal scale.
3.2 Comparing DEA and SFA
As described earlier, DEA and SFA take different approaches to establishing the
location and shape of the production frontier, and
organization is located in relation to the frontier. Here we briefly summar
differences. This is important because these differences are the reasons why the
techniques produce different estimates of the relative efficienc
organizations.
SFA controls for supposed influences on output, and contends that unexplained
variations in output are due
econometric models, therefore, where interest lies in the expl
models extract organization
part of the model. The implication is that standard econometric tools to test model
specification cannot be applied to SFA models both because of the
placed on kε
and because organ
required. Thus un-testable judgments need to be made about the adequacy of
Figure 2: An example of a DEA frontier enveloping a cloud of observations
eterminants of hospital costs and performance variation
DEA models can be run for both constant returns to scale (CRS) and a more flexible
variable returns to scale (VRS) (as shown in Figure 2) which may be appropriate
tions can be considered to be operating at an optimal scale.
Comparing DEA and SFA
As described earlier, DEA and SFA take different approaches to establishing the
location and shape of the production frontier, and to determining where each
tion is located in relation to the frontier. Here we briefly summar
differences. This is important because these differences are the reasons why the
techniques produce different estimates of the relative efficiency of individual
SFA controls for supposed influences on output, and contends that unexplained
variations in output are due – in part, at least – to inefficiency. Unlike standard
econometric models, therefore, where interest lies in the explanatory variables, SFA
tion-specific estimates of inefficiency from the unexplained
part of the model. The implication is that standard econometric tools to test model
specification cannot be applied to SFA models both because of the
and because organization-specific rather than average estimates are
testable judgments need to be made about the adequacy of
: An example of a DEA frontier enveloping a cloud of observations
37
DEA models can be run for both constant returns to scale (CRS) and a more flexible
may be appropriate
tions can be considered to be operating at an optimal scale.
As described earlier, DEA and SFA take different approaches to establishing the
to determining where each
tion is located in relation to the frontier. Here we briefly summarize these
differences. This is important because these differences are the reasons why the
y of individual
SFA controls for supposed influences on output, and contends that unexplained
to inefficiency. Unlike standard
anatory variables, SFA
mates of inefficiency from the unexplained
part of the model. The implication is that standard econometric tools to test model
specification cannot be applied to SFA models both because of the interpretation
specific rather than average estimates are
testable judgments need to be made about the adequacy of
: An example of a DEA frontier enveloping a cloud of observations
Determinants of hospital costs and performance variation
stochastic frontier models and the inefficiency estimates th
2005).
In applying DEA the location and shape of the frontier are established by the data.
The outermost observations, those with the highest level of output given their scale
of operation, are deemed efficient. Referring back to figures 1 and 2, DEA would
consider observations lying at the upper extreme of the data cloud to be fully
efficient, whereas SFA may consider that these organ
inefficiency.
The consequence of plotting the frontier through the outermost observations is that
DEA is highly flexible, the frontier moulding itself to the data. The drawback, though,
is that the frontier is sensitive to organ
combinations of inputs or outputs. These will have a scarcity of adjacent reference
observations (usually termed
being inappropriately positioned.
While DEA might be thought to win out over the SFA method in terms of flexibility,
this is offset by how the technique interprets any di
are two key differences. Firstly, DEA assumes correct model specification and that all
data are observed without error while SFA allows for the possibility of modelling and
measurement error. Consequently, even if the two te
frontier, SFA efficiency estimates are likely to be higher than those produced by DEA.
Secondly, DEA uses a selective amount of data to estimate each organ
efficiency score. DEA generates an efficiency score for each o
comparing it only to peers that produce a comparable mix of outputs. This has two
implications.
(1) If any output is unique to an organ
make a comparison, irrespective of the fact that it may produce
common outputs. An absence of peers results in the automatic assignation of
full efficiency for the organ
eterminants of hospital costs and performance variation
stochastic frontier models and the inefficiency estimates they yield (Smith and Street
applying DEA the location and shape of the frontier are established by the data.
The outermost observations, those with the highest level of output given their scale
of operation, are deemed efficient. Referring back to figures 1 and 2, DEA would
observations lying at the upper extreme of the data cloud to be fully
efficient, whereas SFA may consider that these organizations exhibit some degree of
The consequence of plotting the frontier through the outermost observations is that
is highly flexible, the frontier moulding itself to the data. The drawback, though,
is that the frontier is sensitive to organizations that have unusual types, levels or
combinations of inputs or outputs. These will have a scarcity of adjacent reference
bservations (usually termed “peers”), perhaps resulting in sections of the
being inappropriately positioned.
While DEA might be thought to win out over the SFA method in terms of flexibility,
this is offset by how the technique interprets any distance from the frontier. There
are two key differences. Firstly, DEA assumes correct model specification and that all
data are observed without error while SFA allows for the possibility of modelling and
measurement error. Consequently, even if the two techniques yield an identical
frontier, SFA efficiency estimates are likely to be higher than those produced by DEA.
Secondly, DEA uses a selective amount of data to estimate each organ
efficiency score. DEA generates an efficiency score for each o
comparing it only to peers that produce a comparable mix of outputs. This has two
If any output is unique to an organization, it will have no peers with which to
make a comparison, irrespective of the fact that it may produce
common outputs. An absence of peers results in the automatic assignation of
full efficiency for the organization under consideration.
38
(Smith and Street
applying DEA the location and shape of the frontier are established by the data.
The outermost observations, those with the highest level of output given their scale
of operation, are deemed efficient. Referring back to figures 1 and 2, DEA would
observations lying at the upper extreme of the data cloud to be fully
tions exhibit some degree of
The consequence of plotting the frontier through the outermost observations is that
is highly flexible, the frontier moulding itself to the data. The drawback, though,
tions that have unusual types, levels or
combinations of inputs or outputs. These will have a scarcity of adjacent reference
), perhaps resulting in sections of the “frontier”
While DEA might be thought to win out over the SFA method in terms of flexibility,
stance from the frontier. There
are two key differences. Firstly, DEA assumes correct model specification and that all
data are observed without error while SFA allows for the possibility of modelling and
chniques yield an identical
frontier, SFA efficiency estimates are likely to be higher than those produced by DEA.
Secondly, DEA uses a selective amount of data to estimate each organization’s
efficiency score. DEA generates an efficiency score for each organization by
comparing it only to peers that produce a comparable mix of outputs. This has two
tion, it will have no peers with which to
make a comparison, irrespective of the fact that it may produce other
common outputs. An absence of peers results in the automatic assignation of
Determinants of hospital costs and performance variation
(2) When assigning an efficiency score to an organ
frontier, only its peers are considered, wi
remainder of the sample discarded. In contrast, SFA appeals to the full
sample information when estimating relative efficiency.
In addition to making greater use of the available data, this facet of the SFA
approach will make the sample’s efficiency estimates more robust in the presence of
outlier observations and to the presence of atypical input/output combinations. But
this advantage over DEA is mainly a matter of degree
the DEA frontier may be determined by outliers, but outliers also exert influence on
where the SFA frontier is positioned. Moreover, there are no statistical criteria for
sorting these unusual observations into outliers or
and Street 2005).
eterminants of hospital costs and performance variation
When assigning an efficiency score to an organization not lying on the
frontier, only its peers are considered, with information pertaining to the
remainder of the sample discarded. In contrast, SFA appeals to the full
sample information when estimating relative efficiency.
In addition to making greater use of the available data, this facet of the SFA
make the sample’s efficiency estimates more robust in the presence of
outlier observations and to the presence of atypical input/output combinations. But
this advantage over DEA is mainly a matter of degree – the location of (sections of)
may be determined by outliers, but outliers also exert influence on
where the SFA frontier is positioned. Moreover, there are no statistical criteria for
hese unusual observations into outliers or examples of best practice
39
tion not lying on the
th information pertaining to the
remainder of the sample discarded. In contrast, SFA appeals to the full
In addition to making greater use of the available data, this facet of the SFA
make the sample’s efficiency estimates more robust in the presence of
outlier observations and to the presence of atypical input/output combinations. But
the location of (sections of)
may be determined by outliers, but outliers also exert influence on
where the SFA frontier is positioned. Moreover, there are no statistical criteria for
examples of best practice (Smith
Determinants of hospital costs and performance variation
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