medication adherence in diabetic mellitus: a review of … adherence in diabetic mellitus: a review...
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Boston University
OpenBU http://open.bu.edu
Theses & Dissertations Boston University Theses & Dissertations
2014
Medication adherence in diabetic
mellitus: a review of barriers and
interventions
Zhan, Senmiao
http://hdl.handle.net/2144/14654
Boston University
BOSTON UNIVERSITY
SCHOOL OF MEDICINE
Thesis
MEDICATION ADHERENCE IN DIABETIC MELLITUS: A REVIEW OF
BARRIERS AND INTERVENTIONS
by
SENMIAO ZHAN
B.S., Duke University, 2011
Submitted in partial fulfillment of the
requirements for the degree of
Masters of Science
2014
© 2014 by SENMIAO ZHAN All rights reserved
Approved by
First Reader Abdulmaged Traish, M.B.A., Ph.D. Professor of Biochemistry
Second Reader Elizabeth J. Rourke, M.D. Instructor in Medicine
iv
DEDICATION
I would like to dedicate this work to my fiancé Stuart and my parents.
v
ACKNOWLEDGMENTS
I would like to thank Dr. Rourke for the great opportunity to conduct research at
Boston Medical Center and reviewing my thesis in depth. I would also like to
thank Dr. Traish for reading my thesis as well.
vi
MEDICATION ADHERENCE IN DIABETIC MELLITUS: A REVIEW OF
BARRIERS AND INTERVENTIONS
SENMIAO ZHAN
ABSTRACT
Poor adherence is common in patients with diabetes mellitus and other
chronic diseases that require extensive self-management. This behavior has
been linked to increased complications, mortality rate, and health care costs.
Although much effort has been put into studying the barriers to adherence and
ways to improve both patient self-care and clinical outcomes, little success can
be observed in the long run. Literature review of studies related to medication
adherence in diabetes has shown a lack of uniformity in study parameters and
statistical analysis making the juxtaposition of studies difficult and unreliable.
Intervention studies in the field have shown general improvement in adherence
rate in a short period of time, but rarely making any significant differences in
clinical outcomes. Since diabetes mellitus is a chronic disease, it would be
important to design studies measuring long term effects of interventions in the
future.
vii
TABLE OF CONTENTS
TITLE……………………………………………………………………………………...i
COPYRIGHT PAGE………………………………………………………………….....ii
READER APPROVAL PAGE……………………………………………………...…..iii
DEDICATION .......................................................................................................iv
ACKNOWLEDGMENTS ....................................................................................... v
ABSTRACT ..........................................................................................................vi
LIST OF TABLES .................................................................................................ix
LIST OF FIGURES ............................................................................................... x
LIST OF ABBREVIATIONS ..................................................................................xi
INTRODUCTION .................................................................................................. 1
Medication adherence ....................................................................................... 5
Identify poor adherence .................................................................................. 12
Improvement of poor medication adherence ................................................... 13
PUBLISHED STUDIES ....................................................................................... 20
RESULTS ........................................................................................................... 21
Diabetic adherence studies without intervention ............................................. 21
Intervention ..................................................................................................... 29
Adherence studies on non-diabetic diseases .................................................. 38
viii
DISCUSSION ..................................................................................................... 40
Baseline adherence rate and HbA1c ................................................................ 40
Poor adherence and barriers to adherence .................................................... 41
Intervention ..................................................................................................... 43
CONCLUSION .................................................................................................... 47
REFERENCES ................................................................................................... 49
VITA ................................................................................................................... 57
ix
LIST OF TABLES
Table Title Page
1 Methods used in studying medication adherence 9
2 General overview of interventions to improve
adherence
14
3 Diabetic adherence studies 22-23
4 Average HbA1c 24
5a Average adherence rate (%) 25
5b Weighted average of adherence rate (%) 25
6 Factors associated with non-adherence 28
7 Overview of intervention studies 35-37
x
LIST OF FIGURES
Figure Title Page
1 Major complications from diabetes 2
2 Medical cost breakdown 16
xi
LIST OF ABBREVIATIONS
BGM ............................................................ Blood Glucose Monitoring Frequency
BID ...................................................................................................... Twice Daily
CDC ............................................................................ Centers for Disease Control
CMG ...................................................... Continuous measure of Medication Gaps
CVD ................................................................................. Cardiovascular Disease
DM .............................................................................................. Diabetes Mellitus
HbA1c ......................................................................................... Hemoglobin A1c
MARS ............................................................ Medication Adherence Report Scale
MDKT ............................................................. Michigan Diabetes Knowledge Test
MMAS .......................................................... Morisky Medication Adherence Scale
MPR ........................................................................ Medication Possession Ratio
OD ....................................................................................................... Once Daily
OHA ............................................................................. Oral Hypoglycemic Agents
PDC ............................................................................ Proportion of Days Covered
RAAS ....................................................... Renin Angiotensin Aldosterone System
SDSCA .................................................. Summary of Diabetes Self-Care Activities
T1DM .............................................................................. Type 1 Diabetes Mellitus
T2DM .............................................................................. Type 2 Diabetes Mellitus
1
INTRODUCTION
Diabetes Mellitus (DM), or diabetes, is a serious and complex metabolic
disease that disturbs the lives of millions globally (Guariguata et al., 2013).
According to the Centers for Disease Control (CDC), about 25.8 million people in
the United States alone were affected by diabetes in the year of 2010, and about
35% of adults above the age of 20 are prediabetic based on their hemoglobin
A1c (HbA1c) levels (CDC, 2011). Although much new information has been
gained through various scientific studies regarding the cause of diabetes
(Schulze & Hu, 2014), there is a fast growing trend in the prevalence of the
disease (Danaei et al., 2011; Guariguata et al., 2013). With more people being
diagnosed and treated for diabetes, there is also an increase in the economic
burden. In 2012, it has been estimated that the expenditure related to diabetes
was about $245 billion ($176 billion in direct medical cost and $69 billion in lost
productivity) in the US (Association, 2013). Due to the substantial costs and
detrimental effects of the disease, prevention and reduction of diabetes is of
great importance.
Generally speaking, DM is a disease where the insufficiency of insulin
and/or tissues’ lack of response to insulin leads to abnormal levels of glucose in
the blood. Although the diagnosis of DM is made primarily through the
concentration of plasma glucose (fasting plasma glucose > 126mg/dL for two
days) (Koeppen & Stanton, 2009), the pathological manifestation of the disease
can be observed through various systems in the body (Figure 1).
2
Cerebral vascular disease Retinopathy Blindness
Coronary heart disease
Nephropathy Renal Disease
Neuropathy (Peripheral nervous system) Ulceration and amputation of foot
Figure 1. Major complications from diabetes: The figure depicts some of the microvascular and macrovascular complications from diabetes
Peripheral vascular disease
3
Complications of prolonged hyperglycemia, or high blood sugar, are
categorized into microvascular and macrovascular. Microvascular complications
include retinopathy, neuropathy, and nephropathy. Retinopathies are retinal
abnormalities and are the leading cause of new onset blindness in the US (Fong
et al., 2004). It has been shown through various studies that highly regulated
glycemic control has protective effects against the development of retinopathy
(Fong et al., 2004). Peripheral nerve dysfunction (neuropathy) can lead to
problems such as sensory loss and paresthesia in patients with DM, particularly
in the lower extremities. In severe cases, foot ulceration and injuries can even
result in amputation. To disturb the body’s homeostasis even more,
hyperglycemia can damage the renal functioning in patients. Nephropathy as a
result of DM is the leading cause of renal failure in the US (Fowler, 2008).
Similar to retinopathy, it has been shown that glycemic control is strongly
associated with decreased incidence of both neuropathy and nephropathy as
well (Fowler, 2008; Gross et al., 2005).
The macrovascular complications of DM manifest themselves as an
accelerated rate of developing atherosclerosis. The thickening of the arterial wall
is likely the result of vascular injuries and chronic inflammation. Due to the
macrovascular complications, diabetic patients are more likely to develop
cardiovascular diseases (CVD), such as coronary artery disease, and have
increased chances of myocardial infarction and stroke (Brownlee, 2001; Fowler,
2008; Koeppen & Stanton, 2009). This chance of developing CVD is augmented
4
when the patient also has hypertension and/or dyslipidemia (Haffner, 1999;
Sowers, Epstein, & Frohlich, 2001).
The majority of diabetic patients can be classified into two groups. Type 1
DM (T1DM), or insulin-dependent DM, accounts for a small portion of the diabetic
patient population. It is hallmarked by the destruction of beta cells in the
pancreas, often occurring through autoimmune mechanisms. Since beta cells
are the producers of insulin, T1DM patients have impaired insulin production;
therefore, exogenous insulin is an effective treatment to help prevent ketosis.
The vast majority of the T1DM patients are diagnosed in childhood, but the onset
can happen any time. Type 2 DM (T2DM), on the other hand, makes up about
90% of the diagnosed diabetic population. T2DM differs from T1DM in that
individuals are still able to produce insulin, either normally or at a diminished rate;
however, key organs are unable to sense the presence of insulin. Although the
mechanism varies from case to case, the underlying problem with T2DM seems
to be insulin resistance (Koeppen & Stanton, 2009).
Due to the complex nature of the disease, treatment for T2DM can be very
complex. In order to gain glycemic control, patients may need to take certain oral
treatments and/or insulin along with adhering to careful diet plans and exercise
regimes. Additionally, patients also have to monitor their blood glucose
regularly. With the progression of the disease, patients have to take additional
medications to manage the microvascular and macrovascular complications. In
5
other words, glycemic control is strictly dependent on the patients’ abilities to
self-manage.
Medication adherence
In order to measure how well patients follow their medication regime,
concepts such as persistence, adherence, and compliance have been used in
literature (Cramer, 2004; Kravitz & Melnikow, 2004; Osterberg & Blaschke,
2005). It should be noted that the definition of these terms are not uniformly
accepted. Some consider compliance and persistence to be synonymous with
adherence, where the terms are defined as “the extent to which a patient is
consistent in following medical or health advice (Dunbar-Jacob & Mortimer-
Stephens, 2001; Haynes, Ackloo, Sahota, McDonald, & Yao, 2008).” Others
consider persistence as the duration for which a patient is adherent or compliant
to certain medications (J. K. Lee, Grace, & Taylor, 2006). Some literature even
suggests that “adherence” is a better term because “compliance” is making the
assumption that the patient is passively following doctor’s orders (Osterberg &
Blaschke, 2005). Either way, the assessment of medication utilization behavior
can be critical to the outcome of the treatment due to the obvious reason that, if a
patient is not taking the medication as prescribed, the intended therapeutic
effects cannot occur. For the purpose of this paper, adherence and compliance
will be used interchangeably.
6
Clinical studies of medication adherence have shown varied results. In a
2004 quantitative review of adherence studies from the past five decades, it was
found that, within the 569 studies assessed, the rate of adherence ranged from
~5% to 100%, with an overall average of ~75% (DiMatteo, 2004). One of the
factors that could contribute to such large variability is the lack of a numerical
consensus on what is considered to be adequate adherence. Although
adherence is a continuous factor that could be expressed in a percentage scale
(100% adherence meaning taking all medications on time), most studies consider
adherence and non-adherence as dichotomous variables, where a cutoff is
established. In an effort to unify measures of adherence in recent publications,
the conventional “good adherence” has been established at greater than 80%
(Dunbar-Jacob & Mortimer-Stephens, 2001); however, it is not uncommon to see
studies using cutoffs higher or lower than 80% (Osterberg & Blaschke, 2005).
Another factor that could contribute to the large disparities in medication
adherence is the type of disease the medications are treating. In the
aforementioned review study, compliance rate was the highest in HIV and lowest
in sleep disorders (DiMatteo, 2004).
Study design can also play a key role in data variation. There are different
methods that studies can utilize to gather patient adherence information, each
with its own set of strengths and weaknesses. The methods can be generally
divided into three groups: direct, indirect-voluntary, and indirect-involuntary.
7
Table 1 provides a summary of each method and its advantages and
disadvantages.
The direct method consists of biochemical measurements, where samples
of body fluids provided by patients are assessed for medications (or the
metabolites), or by directly observing patients taking their medications. These
methods can be fairly impractical because they require constant or frequent
monitoring of the patients. Depending on how frequently the researchers
communicate with the patients, the extra attention could result in overestimation
of patients’ own ability to stay compliant to the medication. Although these types
of studies provide a very detailed and objective data set, it is generally costly and
cannot always be used due to the fact that not all medications have easily
measurable metabolites. The amount of effort required to gather data plus the
costliness of the study makes this method an inadequate way to assess
adherence in a large population (Vermeire, Hearnshaw, Van Royen, &
Denekens, 2001).
The indirect-voluntary measurements for adherence are methods
dependent on patients’ abilities to report information. These methods could
present themselves in the form of surveys with detailed questions regarding
patients’ medication taking behavior or as records kept by the patients in the form
of diaries. Questioning patients regarding their behaviors in the form of
questionnaires can be an inexpensive and simple way to gather data regarding
adherence; however, the study would be susceptible to response bias, where the
8
patients might answer questions based on how they expect the healthcare
providers to want them to answer. When designing studies that gather patient
responses, researchers also need to pay close attention to how each question is
worded because differences in the interpretation of questions can also result in
response biases. Since a healthcare provider’s intention is for the patients to
take their medication and follow the treatment regimes, there could be a gross
overestimation in the adherence rate reported by patients (Vermeire et al., 2001).
The indirect-involuntary group of methods consists of pill counts,
electronic monitoring, and the use of medication refill data. Pill counts are
usually conducted through the pharmacy where pharmacists will count the
remaining number of pills left in a patient’s bottle. When pill counts are
conducted through the patient, it becomes a type of patient self-report, and is
prone to all the biases discussed above in the voluntary section. However, even
when pill count is conducted through the pharmacy, patients still can easily alter
the outcome by discarding the pills or by switching them with other bottles in
order to appear to be following the treatment regimen. Although pill counting is
an attractive method due to its simplicity, it is by no means a good measure of
adherence due to its lack of reliability (Rudd et al., 1988).
9
Table 1. Methods used in studying medication adherence: This table compares the pros and cons of various methods used to measure adherence.
Method Pros Cons
Direct Biochemical measures (levels of drug or its metabolites in body fluids)
Highly accurate for drugs that does not metabolize easily.
Expensive The special attention given to the patient might overestimate adherence Does not work for every medication due to variation in metabolism of each patient.
Directly observe patient taking the medication
Highly accurate Patients could hide pills Overestimation of adherence due to special attention
Indirect voluntary
Patient self-report and surveys
Easily conducted with low cost. Patients could easily alter their answers and distort the data
Patient record/diaries Good longitudinal record Patients could easily alter their answers and distort the data
Indirect involuntary
Pill count Simple and inexpensive. Easily quantifiable data
Patients could easily alter the pill numbers
Electronic monitors Simple and easily quantifiable data
Monitoring devices are very expensive. Patients could out-smart the system and alter data
Pharmacy refill data Data is already entered through pharmacy. Easily obtainable
Prescription refill does not equal actual ingestion of medication
10
As technological advancements are made, electronic monitoring systems
are becoming more available for adherence studies. Electronic devices can
record time stamped data each time the patient opens a bottle or canister. The
newer devices can even transmit such data via internet, making the data
gathering process highly accurate and simplified (J. Hughes, Sterns,
Mastandrea, & Smith, 2013). Through the use of electronic monitoring systems,
phenomena such as “white-coat adherence” and “drug holidays” have been
discovered (Osterberg & Blaschke, 2005; Urquhart, 1997). “Drug holidays”
refers to lapses in medication adherence longer than three days. This happens
to about one sixth of the patient population monthly (Urquhart, 1994). “White-
coat adherence” on the other hand, refers to the phenomenon where patients are
more likely to improve their medication-taking behavior five days prior to and post
an appointment with their provider, and the improvement deteriorates until the
next appointment (FEINSTEIN, 1990). Although this approach to studying
adherence can provide highly precise information on the patients’ medication-
taking behavior, it cannot provide information on whether patients actually ingest
the medication or how much is ingested. The patient can also cheat the system
by taking out the medication without actually ingesting it, or take the wrong
dosage and thus invalidate the data. The high cost of the electronic monitoring
devices also makes it unfavorable to study large sample sizes.
There is an increasing trend in adherence studies to utilize pharmaceutical
refill databases. Although there are many flaws, the refill data for medication has
11
proven to be a good alternative to direct measurements of compliance (Steiner &
Prochazka, 1997). The use of databases is subject to the same type of problems
as the electronic devices and pill counts, where patient might refill medications
without actually ingesting them. Additionally, medication is usually filled on a
monthly basis, making it difficult to assess the patients’ medication-taking
behavior within the month. Regardless, due to the efficiency of current pharmacy
record systems, near complete records are available for a large group of
patients. This means that using the database would give researchers a relatively
cost-effective way to study the behavior of a great sum of patients.
Other factors such as selection bias, small sample size, and
experimenter’s bias can also be attributed to the variations in adherence data.
There is no one perfect strategy to study adherence. Even though the flaws of
experimental designs are known, it is difficult to eliminate the biases due to
limited resources and the nature of the study population.
The rate of medication adherence in T2DM patients is quite low, ranging
from 67-85% for oral hypoglycemic agents (OHAs) to 62-64% for insulin (Cramer,
2004). Poor adherence not only reduces the overall efficacy of medications, but
is also associated with increased complications and higher mortality rates (Ho et
al., 2006). Moreover, with the growing number of patients suffering from
complications and a great number of resources being wasted each year from
medication omission, non-adherence is becoming a substantial economic
burden. All in all, the cost of poor compliance in the United States has been
12
estimated to be around $100 billion each year (D. A. Hughes, Bagust, Haycox, &
Walley, 2001).
Improving medication adherence should be one of the main focuses of
health care providers. It has been shown that patients who maintain a high rate
of medication compliance have significantly reduced rates of hospitalization, thus
costing less in healthcare (Sokol, McGuigan, Verbrugge, & Epstein, 2005).
There are also other losses such as reduced worker efficiency, death, and
treatment for other complications that can perhaps be reduced if a better
adherence rate can be achieved.
Identify poor adherence
The first step towards improving medication compliance is to recognize
poor adherence, especially in T2DM patients where signs of non-adherence
might not be immediately apparent. In the clinical setting, HbA1c is often used as
a tool to measure a patient’s long-term glycemic control. HbA1c is hemoglobin
that has been glycated by exposure to plasma glucose. Since the life-span of
hemoglobin is usually 120 days, once the hemoglobin goes through glycation, it
will stay glycated for the remainder of its life time. This feature makes HbA1c a
great marker because elevated levels of glycated hemoglobin would indicate
prolonged hyperglycemia. Patients who are compliant to medication had
generally lower HbA1c than those who are not. One study was able to utilize a
set of questionnaires called the Morisky score in conjunction with HbA1c to
13
identify poorly adherent patients (Krapek et al., 2004). There are other factors
associated with patients at a higher risk for medication non-adherence such as
age, race, and socio-economic status that will be expanded upon later.
Improvement of poor medication adherence
Once the identification of non-adherence is achieved, there needs to be
interventions to improve medication compliance. The types of interventions for
medication adherence can generally be categorized into five groups: cost based,
convenience based, reward based, communication based, and finally a
combination of intervention groups. Table 2 shows an overview of the groups of
interventions and some examples of how the interventions could be utilized.
Although not all of these interventions have been studied with diabetic patients,
there are similar studies on other chronic diseases such as hypertension and
cardiovascular diseases that diabetes is closely related to. The specific data and
effectiveness of the interventions will be discussed later on.
14
Table 2. General overview of interventions to improve adherence: Five types of interventions with summaries and examples of each.
Type of intervention
Summary Example
Cost based Cost based intervention usually is achieved through changing the cost of medication directly or indirectly leading to either increased or decreased drug acquisition cost.
Decrease copayments
Increase insurance coverage
Convenience based
These interventions usually involve the increase in convenience for the patients to either acquire the medication or to use the medication.
Mail-order pharmacy
Getting easier access to the pharmacy/medication
Simplified dosage regimen
Simplified packaging
Alternative route of medication administration
Reward based Patients in this type of intervention group either receive rewards as a mean of achieving certain clinical goals, receive rewards in order to help them improve their adherence, or the reward is given at a random chance.
Financial incentives as a reward for achieving certain goals.
Glucometer or blood pressure cuffs awarded to the patients as a mean to increase self-checkups.
A lottery system
Communication based
Increased communication between healthcare provider/patient, patient family/patient, patient/patient in order to educate or remind patients regarding their conditions
Care programs
Counseling through various means
Educational materials
Increased home visits or phone calls
Small group sessions
Combination Two or more of the above interventions used together
Using care programs in conjunction with decreased copayments
15
The cost-based interventions stem from the idea that cost is one of the
main players in causing medication non-adherence. Even if the cost of
medication is covered by insurance, the bills can stack up from the copayments.
In fact, many studies have shown that lack of drug coverage is strongly
associated with decreased use of prescription drugs (Soumerai et al., 2006).
Additionally, this cost-related non-adherence is most prominent in elderly and in
disabled patient populations (Soumerai et al., 2006). There are many sources of
cost regulations that can be considered when designing cost-based interventions
to increase medication adherence. Since penalizing unhealthy behavior by
increasing cost is unethical and has definitive adverse effect on medication
adherence (Doshi, Zhu, Lee, Kimmel, & Volpp, 2009), it should be avoided at all
cost. Figure 2 displays the general breakdown of medical costs based on patient
and health insurance. Several sources of cost contributing to the out-of-pocket
cost from patients can be observed. From an intervention stand point, the
easiest way to reduce expenses is to perhaps reduce copayment, since it is
usually a flat rate. Other approaches would be to reduce the patient portion of
coinsurance, decrease the deductible limit, increase coverage for medication, or
reduce premiums.
16
Total Cost
Copayment
Coinsurance
Insurance Patient
Deductible
Travel and other
expenses
Premiums
Exclusions
Figure 2. Medical cost breakdown: This figure shows the general cost breakdown of medical expenses for a patient that has health insurance.
17
Convenience based interventions focus on alleviating any inconveniences
in the process of acquiring or administering the medication for the patients. One
example of such an intervention is to give patients easier access to their
medication by using mail-order pharmacies instead of traveling to their local
pharmacies since the medication possession rate is higher in patients who use
mail-order pharmacies (Duru et al., 2010).
From adherence studies from the past decades, researchers have found
that frequency of dosing and complexity of treatment regimen is highly correlated
with reduced adherence (Dezii, Kawabata, & Tran, 2002; Donnan, MacDonald, &
Morris, 2002; Girvin, McDermott, & Johnston, 1999; Ingersoll & Cohen, 2008).
Dosage simplification and specialized packaging are both examples of
interventions based on adding convenience to taking medication.
Reward based interventions have been used in many studies to reinforce
certain behaviors such as smoking cessation, weight loss, and medication
adherence (Burns, 2007; Volpp, John, et al., 2008; Volpp et al., 2009). The way
in which rewards are given can vary between studies. Although the type of
rewards are usually financial incentives such as cash payments and shopping
vouchers, there are also examples of shortening jail sentences as a reward to
improve psychiatric treatment adherence (Monahan et al., 2005). In another
study based on medication use (Volpp, Loewenstein, et al., 2008), the
researchers used a lottery system in conjunction with electronic monitoring
devices.
18
Communication based interventions have been used widely through
medication adherence studies because it can take various forms. This category
of intervention methods can be further divided based on the benefits they
provide. Instructional interventions provide patients with more knowledge
regarding their disease, potential complications, and self-management plans. In
addition to oral communication, these can take the form of written materials and
learning programs. Another method of communication based intervention works
through reinforcement of compliance to medication schedules. These can
include automated telephone calls, electronic monitoring systems, or casual
reminders from health care providers, either through phone calls, home visits, or
office visits. A third method of communicative intervention works through
structured counseling programs. These programs could take the form of group
or individual sessions, where patients can discuss social, economic, and
emotional factors that might otherwise deter them from adherence.
Combined interventions usually mix a communication based intervention
with some other intervention category. An example of a combined intervention
would be providing financial incentives to patients while giving them educational
pamphlets detailing the disease’s complications and self-management plans.
The ultimate goal of adherence interventions is not only to alter the
patients’ behaviors, but also to improve health conditions. For diabetic patients,
this means reduced HbA1c levels, rates of microvascular and macrovascular
complications, inpatient and outpatient hospital visits, and mortality rates. This
19
means that interventions must have a persisting effect, lasting long after the
intervention period ends. One of the goals this paper is to compare various
intervention methods and assess their relative effectiveness in both increasing
medication adherence and improving clinical outcomes.
20
PUBLISHED STUDIES
Literature searches were conducted through Google Scholar, PubMed,
and Web of Knowledge, inputting keywords that generally relate to medication
adherence in diabetes (eg. adherence, compliance, non-adherence, intervention,
diabetes, and diabetes mellitus). Instead of conducting an exhaustive review that
encompasses all of the literature published about the topic in the past two
decades, a limited number of reviews and studies were selected due to study
design and relevancy to this paper. Relevant review articles were further
reviewed and screened for citation of studies that fit the search criteria.
Initially, articles were separated into two groups: medication adherence
studies for diabetes, and adherence studies for non-diabetic diseases. The
diabetic articles were further divided into “measures of behavior and/or HbA1c
only”, “intervention with measures of behavioral outcomes”, and “intervention with
measure of both behavioral and clinical outcomes”. The “measures of behavior
and/or HbA1c only” articles will be used to distinguish factors that help identify
non-adherence, while the intervention articles will be assessed for effectiveness
of the said interventions. Each article will be reviewed for study design, standard
of adherence, outcomes, strengths, and weaknesses.
21
RESULTS
Diabetic adherence studies without intervention
An overview of the studies reviewed with measurements of adherence
behavior and associated HbA1c are presented in Table 3. Out of the fourteen
studies in this category, seven are based on self-reported adherence data
(including Morisky scales), six on pharmacy refill data, and one on electronic
monitoring device data. Although many studies included both T1DM patients and
T2DM patients, the majority of the patients have T2DM due to the prevalence in
the population and age restrictions. Nine studies gathered adherence data for
general prescription medications of the patients and did not exclude non-diabetic
medication. Nine studies provided some kind of HbA1c data, three of which
defined certain levels of HbA1c as categorical values and reported the percentage
of population that falls under these categories.
22
Table 3. Diabetic adherence studies: This is an overview of the diabetic adherence studies that contain measurements with no intervention.
Reference T2 / T1
Duration of Study
n Age (years) Medication Adherence Method
Adherence Rate
HbA1c (%)
(Grant, Devita, Singer, & Meigs, 2003)
T2 -- 128 66 ± 12 4.1 ± 1.9 types Self-report (out of 7days)
6.7 ± 1.1 days 7.7 ± 1.5
(Ciechanowski, Katon, & Russo, 2000)
Both 120 days 367 61.3 ± 11.7* OHA (Oral Hypoglycemic Agents)
Refill data (days in OHA interruption)
Depression Low 7.1 ± 12 Med 9.3 ± 15.5 High 14.9 ± 20.0
--
(Broadbent, Donkin, & Stroh, 2011)
Both -- T1 49 T2 108
43.2 ± 20.6 T1, 58.0 ± 11.3 T2
Mixed Self-report Insulin 86%
--
(Donnelly, Morris, & Evans, 2007)
T2 6.75 yrs 1099 61.5 ± 11.9 Insulin Database (>80% MPR cutoff)
71 ± 18 % 8.5 ± 1.3
(Lin et al., 2004) Both 2 yrs 4385 63.3 ± 13.4 OHA Pharmacy data (days not covered)
80.5 %* 7.8 ± 1.6
(Pladevall et al., 2004)
Both 3 years 677 63.9 ± 10.6 OHA; 2.1 types
Refill data gaps >20% non-adherent.
Metformin 57%*
8.0 ± 1.4
(Bailey et al., 2012) Both -- 59 50.4 ± 10.3 Mixed. >50% taking 3 or more.
Morisky Scale (0-6 = non-adherent 7-8 = adherent)
44.1% --
(Al-Qazaz et al., 2011)
T2 -- 505 58.2 ± 9.2 Mixed. Median 4.0
Morisky Scale Median 6.5 Good (≤6.5) 20.8%, Poor (≥6.5)79.2%
* indicates an adherence number calculated by subtracting non-adherence data.
23
Table 3 continued. Diabetic Adherence Studies: This is an overview of the diabetic adherence studies that contain measurements with no intervention.
Reference T2 / T1
Duration of Study
n Age (years) Medication
Adherence Method
Adherence Rate
HbA1c (%)
(Stuart et al., 2011)
Both 3 years Statin 1139 RAAS 1766
~85% > 65 y.o. Mixed Logs and Pharmacy Receipts (Diaries). Medication Possession Ratios (MPR)
Median MPR RAAS = 0.88 Statins = 0.77. % adherence RAAS >50% Statin <50%
--
(Ngo-Metzger, Sorkin, Billimek, Greenfield, & Kaplan, 2012)
T2 2 yrs 1135
White 61±10.8, 68.7±8.9 Viet, 55.6±10.9 Mex
Mixed Self-Report White 72.8% Vietnamese 72.4% Mexican 46.8%
Poor Glucose Control = A1C >/= 8%. White: Poor = 15.6%, Viet: Poor = 10%, Mex: Poor = 45.2%, p<0.001
(Osborn et al., 2011)
Both -- 383 54.4±13.0 Mixed Self-Report, SDSCA Scale Score (out of 7 days)
Average 6.7 ± 1.0
Average 7.6 ± 1.7, White 7.4±1.5, Black 7.9 ± 1.9, p=0.005
(Aikens & Piette, 2013)
T2 -- 287 56.4±8.7 Mixed 4 Item Morisky Scale
51% 59% of participants had HbA1c>7%
(Nagrebetsky et al., 2012)
T2 1-2yrs 1yr 161 Non 50
1yr 63.5 ± 10.4 non 62.1 ± 11.7
1yr 5.0 ± 2.5 Non 4.6 ± 2.8
Electronic Monitoring system (TrackCap) Medication Adherence Report Scale (MARS, scale ranged from 5-25)
TrackCap 1yr 75.5 ± 28.3 non 68.2 ± 28.8 MARS: (avg) 1yr 24 Non 25
1yr 8.2 ± 1.1 non 8.6 ± 1.4
(Virdi, Daskiran, Nigam, Kozma, & Raja, 2012)
T2 365 days 5172 51.4 ± 8.4 Non-insulin
Refill Data MPR (>80%)
44.4% --
24
Table 4. Average HbA1c: The mean and standard deviation of HbA1c from seven studies
Reference n Mean HbA1c (%) Standard Deviation
(Grant et al., 2003) 128 7.7 1.5
(Donnelly et al., 2007) 1099 8.5 1.3
(Lin et al., 2004) 4385 7.8 1.6
(Pladevall et al., 2004) 677 8.0 1.4
(Osborn et al., 2011) 383 7.6 1.7
(Nagrebetsky et al., 2012)
161 8.2 1.1
50 8.6 1.4
Weighted Mean and pooled SD: 7.9 1.5
Average percentages of HbA1c were given by six studies. They ranged
from 7.6% to 8.6% with a weighted average of 7.9% and a pooled standard
deviation of 1.5% (Table 4). The Nagrebetsky data was divided into two groups
and thus accounted for two separate samples when the weighted average was
calculated (Nagrebetsky et al., 2012). Percentages of adherence were
presented by nine studies (Table 5a) and ranged from 44.1% to 86%. The
weighted average for all nine studies came out to be 61.4 ± 15.8% (Table 5b). A
comparison of the weighted average of adherence rate for six self-report studies
and four database studies was carried out in Table 5b. A p-value was produced
as a result of a t-test for the null hypothesis that the self-report average was
different from the database average (H0: μself-report ≠ μdatabase). Since p= 0.47, the
analysis was not statistically significant and the null is rejected, indicating that the
average adherence from self-reported data was not significantly different from
the database average.
25
Table 5a. Average adherence rate (%): Percent of patient adherent in ten studies
Reference Method n Adherence rate (%)
(Broadbent et al., 2011) Self-report 157 86
(Ngo-Metzger et al., 2012) Self-report (Non-hispanic white)
249 72.8
(Ngo-Metzger et al., 2012) Self-report (Vietnamese)
194 72.4
(Ngo-Metzger et al., 2012) Self-report (Mexican)
533 46.8
(Bailey et al., 2012) Self-report Morisky scale 59 44.1
(Aikens & Piette, 2013) Self-report Morisky Scale 287 51
(Donnelly et al., 2007) Refill data (>80% MPR) 1099 71
(Lin et al., 2004) Refill data (>80% MPR) 4385 80.5
(Pladevall et al., 2004) Refill data (<20% CMG*) 677 57
(Virdi et al., 2012) Refill data (>80% MPR) 5172 44.4
*CMG = continuous measure of medication gaps
Table 5b. Weighted average of adherence rate (%): Calculated average adherence rate of studies in Table 5a.
Total Self-report Refill data p-value
61.4 ± 15.8% 59.4 ± 17.4% 61.7 ± 15.9% p= 0.47
26
Several studies have noted the significant association between increased
medication adherence and improved clinical outcomes, especially in long term
metabolic control (Aikens & Piette, 2013; Al-Qazaz et al., 2011; Donnelly et al.,
2007; Pladevall et al., 2004). One study noted that there is no significant
association between glycemic control and age, gender, or social deprivation
(Donnelly et al., 2007). Other studies attempted to control for various factors
that might have affected the outcome of the adherence data (Table 6).
Grant et al hypothesized that the number of prescription medications a
patient has to take can contribute to poor adherence (Grant et al., 2003). They
utilized correlation studies and found the Spearman’s correlation coefficient for
number of medications taken and adherence rate to be 0.07 (p= 0.4). The
finding was not statistically significant.
Two studies focused on the effect of depression on compliance to diabetic
medication regimen (Ciechanowski et al., 2000; Lin et al., 2004). Both studies
only focused on OHAs and found that there is significant evidence (p<0.05,
p<0.005 respectively) that patients with major depressive symptoms tend to have
poorer adherence to diabetic medication.
The study by Bailey et al concluded that the significant (p<0.05) factors
that are associated with medication non-adherence are “cost, no refills, poor
health status, fewer disease states, and any reason at all to not take medication
(Bailey et al., 2012).” When diabetic knowledge was assessed, Al-Qazaz et al
found that patients with better glycemic control (HbA1c ≤ 6.5) had higher
27
adherence rates (p<0.001) and also more knowledge about diabetes (p<0.001)
(Al-Qazaz et al., 2011).
When adherence rate was assessed by race, it was clear that Mexican
Americans and African Americans had the lowest adherence rates compared to
Whites in the US (Ngo-Metzger et al., 2012; Osborn et al., 2011). Ngo-Metzger
et al found that more Mexican Americans reported to have financial barriers and
lower overall income compared to Whites and Vietnamese Americans (Ngo-
Metzger et al., 2012). Osborn et al. found that while African Americans had
significantly lower adherence rate (p<0.05), they also had lower health literacy
(Osborn et al., 2011). When numeracy was assessed, no significant results were
found.
28
Table 6. Factors associated with non-adherence: This shows some studies that tried to control for factors that associate with non-adherence
Reference Factor studied Results Significance Conclusion
(Grant et al., 2003)
Number of medication taken by patient
Spearman’s correlation coefficient for number of medication vs. adherence = 0.07
p=0.4 Not significant
Virtually no correlation between total number of medication and average medication adherence
(Ciechanowski et al., 2000)
Depression Depression & Adherence (% days in OHA interruptions) Low dep. 7.1 ± 12 Med dep. 9.3 ± 15.5 High dep.14.9 ± 20.0
p<0.05 Significant
Depression severity is significantly associated with poor adherence
(Lin et al., 2004)
Depression Major dep. 24.5% non-adherence No Major dep 18.8% non-adherence
p<0.005 Significant
Depression is significantly associated with non-adherence
(Bailey et al., 2012)
Access, barriers, medication use, and demographics
Adherence data for specific categories were not given
P<0.05 for Cost, no refills, poor health status, fewer disease states, and any reason
Cost, no refills, poor health status, fewer disease states, and having any reason at all are significantly associated with non-adherence.
(Al-Qazaz et al., 2011)
Diabetes knowledge
A1c ≤ 6.5 10 MDKT* 8 MMAS † MDKT*
p<0.001 MMAS
†
p<0.001 More knowledge about diabetes is correlated with better adherence rate and better glycemic control.
A1c > 6.5 7 MDKT* 5.8 MMAS †
(Ngo-Metzger et al., 2012)
Financial barriers and race
Adherence White 72.8%
Viet 72.4%
Mexican 46.8%
p<0.001 for all measures between white and Mexican or Viet and Mexican
Mexicans had lower adherence rate and poor glycemic control. Mexicans also reported more financial barrier.
A1c≥8% 15.6% 10.0% 45.2%
(Osborn et al., 2011)
Race, Diabetes literacy, and numeracy
White Adherence 6.8 ± 0.8 SDSCA
‡
Black Adherence 7.9 ± 1.9 SDSCA
‡
p<0.05 African Americans had lower adherence, but this could be due to health literacy. Health literacy vs. Adherence r=-0.1 p<0.02
* MDKT = Michigan Diabetes Knowledge Test (0-14). Higher score indicates more knowledge. † MMAS = Morisky Medication Adherence Scale (0-8). Higher score indicates better adherence.
‡ SDSCA = Summary of Diabetes Self-Care Activities. This is the number of days being adherent to medication in the past 7 days.
29
Intervention
Twelve studies were reviewed regarding interventions to improve
medication adherence in diabetes (Table 7). Although many studies measured
MPR as a means of adherence, due to the differences in measurement methods,
the results are difficult to compare across studies.
One study (Maciejewski, Farley, Parker, & Wansink, 2010) utilized a cost-
based intervention in which the researchers studied enrollees in a value-based
insurance design program, from which the sample of the intervention group was
drafted. These patients received significant copayment reductions based on the
type of medication prescribed and whether or not the medication was from a
name brand. The control group consisted of patients who were not enrolled in
the value program. Using a pre-post quasi-experimental study design,
Maciejewski et al. assessed changing MPR percentages for a series of
medications. For the purposes of this paper, the data for metformin was
specifically examined. The study showed that there was a significant decrease in
adherence for patients who were not enrolled in the copayment reduction
program (p<0.001). No clinical outcomes were assessed.
Four of the twelve studies can be classified as convenience-based
interventions. Of these four, two studied a change in method of insulin
administration (vial/syringe to pen) in order to increase adherence. Xie et al.
conducted a pre-post study with two groups of patients (Xie et al., 2013). The
intervention group switched to pens, while the control group continued to use
30
vials and syringes. Lee et al., on the other hand, studied the adherence rate of
one group of patients who had switched to pens (W. C. Lee, Balu, Cobden,
Joshi, & Pashos, 2006). Xie et al. demonstrated that there was a significant
difference between the intervention group and the control group in adjusted
MPRs after the switch (p<0.05). They also showed that persistence was
significantly longer for patients who had switched to the insulin pen (p<0.0001).
The other study showed that the percentage of patients who met the adherence
cutoff (MPR > 80%) increased significantly after switching to insulin pens
(p<0.01). While Lee et al. did not conduct studies on clinical outcome, Xie et al.
observed the change in patients’ HbA1c and found no significant difference
between the intervention group and the control group (p=0.09).
One of the other convenience-based intervention studies examined the
difference in adherence between once-daily and twice-daily dosages for Glipizide
(Dezii et al., 2002). The study demonstrated that adherence was significantly
greater in once-daily dosage patients (p<0.05). The last convenience-based
intervention study looked at differences in prescription medication acquisition
(Zhang et al., 2011). The intervention group used mail-order pharmacy services,
where prescription medications can be delivered to the patients’ residences
directly, while the control group utilized retail pharmacies. PDC (proportion of
days covered) was assessed, and it was found that the intervention group had a
significantly higher adherence rate (p<0.001). No clinical data was presented by
either of these two studies.
31
Five of the twelve articles fall under the category of communication-based
interventions. Patel et al. and Vervloet et al. conducted their studies with
electronic monitoring devices that could send reminders to patients during the
time in which they needed to take their daily medications (Patel et al., 2013;
Vervloet et al., 2012). Patel et al. performed a pre-post analysis and compared
the PDC ratio of patients before activation of the mobile application and during
the 30days in which the patient utilized the application. The difference between
the pre-activation adherence and the post-activation adherence was not
significant; however, it approached significance (p=0.057). They also had a
seven months follow-up where the adherence rate fell below the pre-activation
period. Vervloet et al. differed from Patel et al.’s study in that the former used a
control group that did not receive a reminder system. They measured “days
without dosing” and found that there was no significant difference between the
intervention and control groups (p=0.283). However, due to the functionality of
the electronic monitoring system, they were able to obtain time stamped
information regarding how readily the patient took the dosage within the allotted
time slot (ranged from 15 – 45 minutes). The difference between the percentage
of doses taken within this time slot between the intervention group and control
group was significant (I: 56.7± 23.8% vs. C: 43.2± 26.2% p=0.003). No clinical
data was obtained through these two studies.
The remaining three of the five communication-based interventions
articles focused on education and emotional support from healthcare providers.
32
Walker et al. examined the effect of telephone calls to patients from health
educators on medication adherence (Walker et al., 2011). The telephone calls
were made to the intervention group and provided information regarding
medication adherence and life style changes. The control group did not receive
telephone calls; however, both groups received printed educational materials.
MPR was calculated from refill data. Although specific numerical data was not
found on the article, the authors reported that there was no significant difference
between those who received phone calls and those who did not.
Shah et al. studied the effects of pharmacist discharge counseling on
adherence (Shah et al., 2013). The intervention group received counseling
regarding their disease status and medication regimen from pharmacists before
being discharged from the hospital, while the control group was not counseled.
The PDC calculated from refill data for the intervention group was significantly
higher than that of the control group (p<0.005). Clinical outcomes were taken
into consideration in the form of long-term glycemic control. The average HbA1c
for the intervention group turned out to be significantly lower that of the control
group (p<0.005).
Stanger et al. was the only T1DM specific study in the intervention study
pool reviewed by this paper (Stanger et al., 2013). This 14-week pre-post study
involved providing adolescents with T1DM motivational counseling in conjunction
with contingency management in order to improve blood glucose monitoring
frequency (BGM). Free glucometers and test strips were also provided to the
33
subjects. This study assessed adherence through self-reported daily frequency
of BGM as part of the treatment regimen. A baseline BGM was established prior
to the introduction of the intervention. It was found that the daily BGM frequency
increased significantly as a result of the intervention (p<0.001). As for the clinical
outcomes, HbA1c decreased significantly over the course of the study (p<0.0001).
Furthermore, a three-month follow-up showed no significant difference in HbA1c
compared to the measurements obtained right after the intervention (p=0.42).
Of the featured articles, two fit within the reward-based intervention
category. Both studies utilized financial incentives as the reward. Austin & Wolfe
studied patient populations that had not had HbA1c or LDL screenings in the past
year (Austin & Wolfe, 2011). Adherence to regular clinical screenings was
assessed through lab results on file. The intervention group received a $6 gas
station gift card every time a lab result was sent to the health-care provider, while
the control group did not receive anything. Although numerical data was not
presented in the article, the authors reported that the intervention group had
significantly higher average number of screenings. The clinical outcome had a
positive trend in HbA1c reduction associated with number of screenings but the
result bore no significance.
Long et al. conducted their research using two different interventions
(Long, Jahnle, Richardson, Loewenstein, & Volpp, 2012). Intervention group 1
was received telephone peer mentoring and the mentors were provided $20
incentive to talk with the subjects every month for six months. Intervention group
34
2 was a reward-based group where they received $100 for achieving 1%
reduction in HbA1c at the end of the six months and $200 for 2-6% reduction. A
control group was also established receiving regular care with the lack of peer
mentoring and financial incentives. Adherence data was obtained through
patient self-report. Intervention group 1 achieved a 79% adherence rate, and
intervention group 2 had an 80% adherence rate compared to the 67% achieved
by the control group. Although a p-value was not presented for the difference in
adherence, it is clear that the numbers are quite different between the
intervention groups and the control group. HbA1c was measured before and after
the study in an effort to assess clinical outcomes. Change in HbA1c was
presented in the article. Although there is no significant change in HbA1c for any
of the groups before and after the study (p>0.05), intervention group 1 had
achieved significantly higher reduction in HbA1c than the control group (p<0.01).
35
Table 7. Overview of intervention studies: Findings from the intervention studies including adherence and clinical outcomes
Reference N Intervention Control Adherence measure and results
Sig. Clinical outcomes
Sig.
(Maciejewski et al., 2010)
nI = 2201 nc= 2201
Enrollment in program for reducing copayment based on need, drug type (band vs. non-brand)
Not enrolled in the program. Normal copayment
MPR %decrease (Metformin) I: ∆ ~0% C: ∆ ~-3.8%
p<0.001 for the difference significant
-- --
(Xie et al., 2013)
nI = 603 nc= 603
Switching from vials/syringe to pens for insulin administration
Continued use of vials/syringe
MPR (adjusted for the difference b/w pen and vial) Intervention: Pre 0.86 ± 0.18 Post 0.79 Persistence: 65.3% Control: Pre 0.86 ± 0.17 Post 0.76 Persistence: 49.8%
MPR post p=0.017 Significant Persistence p<0.0001 significant
∆ HbA1c% I: -0.04% C: -0.24%
p=0.09 Not significant
(W. C. Lee et al., 2006)
n=1156 Pre-post analysis
After switching from vial/syringe to pens for insulin administration
Before switching to pen
MPR (>80% as adherent) I: 54.6% C: 36.1%
p<0.01 significant
-- --
(Dezii et al., 2002)
nOD =746 nBID = 246
Once-daily dosage for Glipizide (OD)
Twice-daily dosage for Glipizide (BID)
Adherence Index (similar to MPR) OD: 60.5% BID: 52%
p=0.027 significant
-- --
I = intervention group C = control group
36
Table 7 continued. Overview of intervention studies
Reference N Intervention Control Adherence measure and results
Sig. Clinical outcomes
Sig.
(Zhang et al., 2011)
nI=1361 nC=1361
Mail-order pharmacy Retail pharmacy
PDC* (same as MPR) I: 49.7% C: 42.8%
p<0.001
-- --
(Patel et al., 2013)
n=50 Pre-post study
I1: During the activation of Pill Phone (Mobile application for medication reminder) I2: Post activation of Pill Phone
Pre-activation of Pill Phone
PDC (same as MPR) I1: 0.58 I2: 0.46 C: 0.54
C vs. I1 p=0.057 approaches significance -- --
(Vervloet et al., 2012)
nI=56 nC=48
Real time medication monitoring system that has customized SMS medication reminder system built in.
Regular care without the real time medication monitoring system
Days without dosing I: 11.9 ± 18.8 C: 13.8 ± 14.5 Dose taken within time period (range from 15min to 45min) I: 56.7% ± 23.8% C: 43.2% ± 26.2%
p=0.283 not significant p=0.003 significant
-- --
(Walker et al., 2011)
nI=262 nc=264
Telephone calls from health educators about medication adherence and life style changes.
Regular care with printed educational materials (intervention group also received printed materials)
MPR Numerical data not presented
p=0.23 for insulin users p=0.39 for non-insulin users Not significant
-- --
*PDC = Proportion of days covered
37
Table 7 continued. Overview of intervention studies
Reference N Intervention Control Adherence measure and results
Sig. Clinical outcomes
Sig.
(Shah et al., 2013)
nI = 64 nc = 64
Pharmacist discharge counseling
Regular care
PDC (same as MPR) I: 55.2% ± 42.0% C: 34.8% ± 37.9%
p=0.004 significant
HbA1c (%) I: 7.8±1.6 C: 9.5±2.9
p=0.003
(Stanger et al., 2013)
n=17 Pre-post study with a follow-up Adolescents with T1DM
Motivational interview and contingency management that targeted increased Blood Glucose Monitoring (BGM). Free glucometer and test strips were provided
Regular care before intervention
Self and parent-report of BGM Average frequency of BGM per day Pre: 4.1±1.9 Post: 6.3±2.0
p<0.001 HbA1c (%) Pre: 11.6 ± 2.5 Post: 9.1 ± 0.9 3m Follow-up: 9.8 ± 1.4
Pre vs. Post p<0.0001 Significant Post vs. Follow-up p=0.42 Not significant
(Austin & Wolfe, 2011)
nI = 464 nc = 2101 Patients lacking HbA1c screening
$6 gas gift card incentive for each lab result received by doctors.
Regular care
Avg number of HbA1c screenings I: 3.34 C: 2.69
Significant difference, p value not given
Positive trend
No significance
(Long et al., 2012)
n1 = 38 n2 = 40 nc = 39 African American veterans with poor diabetes control
I1: Telephone peer mentoring. I2: At the end of six months, $100 for 1% decrease in HbA1c and $200 for 2-6% decrease in HbA1c
Regular care
% of patient with self-reported good adherence I1: 79% I2: 80% C: 67%
Not given ∆HbA1c(%) from baseline I1: -1.08 I2: -0.46 C: -0.01 ∆from C I1: -1.07 I2: -0.45
p>0.05 for all ∆HbA1c from baseline. p<0.01 for I1 vs. C p=0.25 for I2 vs. C
38
Adherence studies on non-diabetic diseases
Many articles were found of adherence studies on non-diabetic disease.
Some of the studies on diseases most relevant to diabetes such as hypertension
and cardiovascular diseases were briefly reviewed.
Irvine et al. examined the difference in adherence and mortality between a
placebo group and a group using amiodarone therapy. Subjects are mainly
acute myocardial infarction survivors. Adherence was measured through pill
count and patients who have an average-count less than the 20th percentile were
considered to be poorly-adherent. The study found that those who are poorly-
adherent in both the amiodarone group and the placebo group had a significantly
increased risk for sudden cardiac death (p<0.01, p<0.05 respectively), total
cardiac mortality (p<0.01, p<0.02), and all-cause mortality (p<0.004, p<0.001).
The study identified that age above 70 years old was a predictor of poor
adherence to placebo (p<0.03). They have also found that the lack of social
activities was also correlated with reduced adherence (p<0.05) (Irvine et al.,
1999).
In a study for hypertension, Friedman et al. conducted an experiment to
assess the effect of a telecommunications system that monitored and counseled
patients on adherence to antihypertensive medications as well as blood pressure
control (Friedman et al., 1996). The control group received usual care with no
telephone systems. Adherence data was evaluated through pill count of
antihypertensive medications. Mean adherence improved significantly for the
39
intervention groups compared to the controls (p<0.05). Blood pressure was
assessed as a mean for clinical outcomes. The mean diastolic blood pressure
decreased significantly for intervention group compared to the controls as well
(p<0.05).
40
DISCUSSION
Baseline adherence rate and HbA1c
The first part of this review was focused on nonintervention diabetic
adherence studies that either helped to establish a baseline adherence rate or
provided insight to certain factors that interfere with adherence. One of the
biggest problems with the studies provided is the lack of standardization in
adherence measurement and analytic strategies. The self-report method
presented the greatest variety in evaluation of adherence. In the seven self-
reported studies, three utilized the Morisky scale of adherence. Although the use
of Morisky scales has provided these three studies with some standardization,
the presentation of results was completely different amongst the studies. Bailey
et al. classified a score of 0-6 as non-adherent and 7-8 as adherent, whereas Al-
Qazaz et al. only provided a median score with no classification.
Studies that used refill data as a source of adherence measurement
showed more uniformity in analysis strategies. With the exception of one, all of
these studies calculated some form of the medication possession ratio and set
the cut-off for whether a subject is considered adherent or not at >80%.
Out of the fourteen articles reviewed in this category, ten articles
evaluated adherence as categorical variables in the form of self-reported status,
Morisky scale scores, or dichotomous variable with a percentage cutoff. These
studies were able to provide percentages of subjects that were adherent during
the study and thus the data was compared. The total average of the proportion
41
of subjects who were considered to be adherent across the ten studies is 61.4 ±
15.8%. This number is slightly lower than the previously reported average
adherence rate of 70% (DiMatteo, 2004); however, this could be due to the fact
that only a limited number of articles were reviewed in this paper.
Since patient self-report has a tendency to overestimate adherence rate
(McDonald, Garg, & Haynes, 2002; Vermeire et al., 2001), the average
adherence rate from the self-reported studies were compared to the average
calculated using refill data. The two averages were not significantly different,
indicating that self-report was just as effective at assessing adherence rate as
the refill data. However, due to the limited number of studies reviewed, this
result lacks power in determining the true difference.
Nine studies out of the twelve provided data on HbA1c. Variation in data
analysis and presentation has once again limited the number of studies that can
be compared. The weighted mean HbA1c of subjects in six studies is 7.9 ± 1.5%
and the data ranged from 7.6% to 8.6%. This number is feasible considering that
the subjects studied are diagnosed with DM (>6.5% HbA1c).
Poor adherence and barriers to adherence
Four studies have confirmed that increased medication adherence rate is
associated with improved long term metabolic control (Aikens & Piette, 2013; Al-
Qazaz et al., 2011; Donnelly et al., 2007; Pladevall et al., 2004); however, it is
unclear whether medication adherence is the main factor contributing to the
42
change in glycemic control. Donnelly et al. has found no significant association
between glycemic control with age, gender, or social deprivation. Since there are
previous reports that old age (>70yrs) is a predictor of poor-adherence (Irvine et
al., 1999), the discrepancy might be due to the study design and patient
population.
Some predictors of poor-adherence are identified through the studies
presented. Identification of patients with poor-adherence would be helpful to
healthcare providers in order to provide interventions. Depression and race
(African American and Mexican American) are shown to be significantly
associated with poor-adherence (Ciechanowski et al., 2000; Lin et al., 2004;
Ngo-Metzger et al., 2012; Osborn et al., 2011); however, these factors are
merely associated with decreased adherence with no demonstrated causation
relationship. For example, Ngo-Metzger et al. found that Mexican Americans
had significantly lower adherence rates that correlated with their overall lower
household income and higher reported financial barriers. In the same study, they
found that financial barriers are associated with lower adherence and higher
HbA1c (p<0.001). Other studies also found that higher healthcare cost is a barrier
to adherence along with other factors such as lack of refills, poor health status,
and poor diet (Bailey et al., 2012; Ciechanowski et al., 2000).
In the case of Osborn et al.’s study, where African Americans had lower
adherence rate compared to whites, they hypothesized that diabetes literacy and
numeracy might be the barrier causing the difference in adherence. The
43
research found significant evidence that low health literacy in African Americans
was one of the reasons explaining the lowered adherence rate, but no clinical
evidence was examined.
Factors that were studied but presented no significant correlation to
adherence are polypharmacy number greater than 1 (number of prescribed
medications is greater than 1), diabetes numeracy, and the utilization of
electronic medication monitoring devices (Grant et al., 2003; Nagrebetsky et al.,
2012; Osborn et al., 2011). Although all three studies had sample sizes (n)
greater than 60, the study could still present biases and confounding variables
that make the factors seem irrelevant even if it is.
Intervention
Twelve intervention studies were reviewed that included at least one of
each of the intervention types discussed in the introduction. Five of the studies
presented both medication adherence and clinical outcomes in the form of HbA1c.
Two studies showed no significant change to the adherence and two other
studies showed no significant change to the long-term glycemic control after
subjects had received the intervention. Three studies used pre-post study
designs and assessed the difference before the intervention and after the
intervention with the same group of subjects. These studies could be
underestimating the effects of the intervention due to the lack of control
44
comparison and the additional effects that time could have on the adherence
rate.
There are several problems with intervention studies as a whole. First of
all, the subject selection process is flawed. Although many studies randomly
select a list of patients who qualify for their study, only the patients who are
voluntarily choosing to participate are recruited. This lack of true randomization
means the intervention studies might fail to evaluate the patient population that
are unwilling to seek care. It would be better to design a study where patients
who are overdue for medical attention be contacted and given information
regarding the study and intervention so that more patients of that type could be
consented into participating in the study.
Secondly, adherence data are often gathered during the intervention
process or a short amount of time following the intervention. It is rare to see any
studies address the long-term benefits of the intervention, or even present data
on what happens when the intervention is terminated. Most follow-up periods are
around three months to six months and one can already observe a decrease in
the previously increasing adherence rate (Patel et al., 2013; Stanger et al.,
2013). Since diabetes is a chronic disease, an intervention should focus on
having a long lasting effect. This means that both interventions and follow-ups
have to last sufficiently long in order to gather meaningful results regarding
adherence.
45
In addition, a number of studies had sample sizes that are too small. A
study with small sample size would lack the power to distinguish differences in
the data. One can calculate the required sample size through tables or statistical
methods. Without an adequately large sample size, it would be difficult to
interpret the data and extrapolate the findings.
It was surprising to see that both studies that focused on electronic
reminder devices failed to make significant differences in adherence rate (Patel
et al., 2013; Vervloet et al., 2012); however, upon closer examination, it seems
that the devices were able to produce significant increase in doses taken by the
patients within the recommended time period. This means that, although the
device did not help increase long term adherence or persistence, it was able to
help patients take their medication at the right time during the day. This could be
very useful for complex medication regimens that require multiple dosages within
a day.
The study done by Long et al. showed rather interesting results. One of
the intervention groups received peer counseling and the mentors received
monthly financial incentives to carry out the peer counseling, while the other
intervention group received one incentive at the very end of the study for
reducing HbA1c. Both groups had significantly higher adherence rate compared
to the control group at the end of the study. However, the clinical outcomes did
not quite match the adherence data. The group that received peer counseling
had significantly lower HbA1c than the control group, but the average HbA1c of the
46
group that received a final incentive was not significantly different from that of the
control. Although this outcome can be interpreted in many ways, it could suggest
that while the second intervention helped increasing adherence rate, some other
factor might have more influence on improving glycemic control, such as the
emotional aspect of interacting with another human being through counseling.
However, the lack of monthly financial incentives given to the patients provides
no assessment of whether financial incentives could work the same way as the
monthly peer mentoring if provided in a shorter period in between.
This idea that adherence rate is not the only factor affecting clinical
outcomes can be further demonstrated by the study conducted by Irvine et al.,
where poor adherence in both the placebo group and the medication group
increased mortality rate significantly. This result suggests that poor adherence to
medication is only part of the problem; there is a greater underlying behavioral
factor that is hindering the effectiveness of treatments.
47
CONCLUSION
Poor adherence is common in patients with DM and other chronic
diseases that require extensive self-management. This behavior has been linked
to increased complications, mortality rate, and health care costs. Although old
age, race, and symptoms of depression are predictors of poor adherence, high
health care costs, poor health status, and poor diet act as barriers preventing
patients from being compliant with their medication regimens.
Much effort has been put into finding ways to improve adherence, and
these interventions have shown varied results in altering medication possession
rates. One of the biggest problems with studies in this field is the lack of
standardized methods in measuring true adherence. The use of pharmacy and
patient self-report data might be more cost-effective, but they provide no
assessment on whether a patient has actually taken the medication. It would be
critical for future studies to incorporate more direct methods such as blood and
urine tests to monitor the actual adherence rate of subjects.
The lack of a meaningful measurement of true adherence also renders the
studies on clinical outcomes less conclusive. From the reviewed intervention
literatures, only three have shown significant improvement in HbA1c. All three
studies used communication based interventions that focused on changing the
subjects’ behaviors as a whole. Although both adherence rate and glycemic
control have improved in these cases, there is no indication that the improved
adherence rate was the cause of these positive clinical outcomes. Furthermore,
48
while some interventions can provide a short-term improvement, there is no
evidence that these interventions can maintain the positive effects consistently
for a long period of time. Since diabetes mellitus is a chronic disease, it would be
important to design interventions that could maintain long-term effects.
The most important question to consider is whether changing medication
adherence alone is enough to solve the problems posed by poor patient self-
care. Perhaps the focus should be shifted towards identifying factors that could
provide enough motivation to the patients to change their behavior and ultimately
improve their health.
49
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57
VITA
SENMIAO ZHAN
Address: 5915 Lyon farm drive Durham, NC 27713 Telephone: (919) 452-3661 Email: [email protected] Year of Birth: 1988 Education: Duke University, Durham, NC
Bachelor in Sciences in Chemistry with a concentration in Pharmacology; May 15, 2011 with Distinction Boston University School of Medicine, Boston, MA Masters of Science in Medical Sciences; May, 2014 Curriculum Highlights Histology, Physiology, Organic Chemistry, Analytical Chemistry, Physical Chemistry, Mammalian Toxicology, Biochemistry, Pathology
Research Experience
09/2013 – present Boston Medical Center Dr. Elizabeth Rourke, MD Massachusetts
Served as a research assistant in a diabetic medication adherence study
08/2009 – 05/2011 Duke University Medical Center Dr. Hiroaki Matsunami North Carolina
Conducted independent study on odorant receptors in mice / Specific skills include: Polymer Chain Reaction, Electrophoresis, DNA mini-prep, Gene sequencing, Cell culture, Cell surface staining, Florescence Activated Cell Sorting, Calcium Imaging, Western Blot, Protein purification
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Clinical Experiences
09/2012 – 05/2013 Volunteer Boston Health Care for the Homeless Program Boston, Massachusetts
Volunteered as a front desk assistant taking phone calls and conducting patient satisfaction surveys
05/2011 – 06/2011 Volunteer 2nd Affiliated Hospital of Shandong University Shandong, China
Volunteered in the pediatrics department conducting simple tasks such as measuring weights and heights of patients
03/2011 – 03/2011 Shadowing Triad Neurological Associates Winston-Salem, North Carolina
Observed Dr. Giles F. Crowell as he examined patients
Work Experiences
09/2007 – 07/2012 Duke University Duke Center for Science Education Durham, North Carolina
Served as a work study student at first, then as a full time Science Education Intern to work on educational materials for high school students
Publications
(2013) Dey, Sandeepa, Zhan, Senmiao, & Matsunami, Hiroaki. (2013). A Protocol for Heterologous Expression and Functional Assay for Mouse Pheromone Receptors Pheromone Signaling (pp. 121-131): Springer.
(2013) Mainland, Joel D, Keller, Andreas, Li, Yun R, Zhou,
Ting, Trimmer, Casey, Snyder, Lindsey L, . . . Zhan, Senmiao… (2013). The missense of smell: functional
59
variability in the human odorant receptor repertoire. Nature neuroscience.
(2011) Dey, S., Zhan, S., & Matsunami, H. (2011). Assaying
surface expression of chemosensory receptors in heterologous cells. J Vis Exp(48). doi: 10.3791/2405