home mechanical ventilation: hmv guidelines. committee members doug mckim and jeremy road :...
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HOME MECHANICAL VENTILATION: HMV GUIDELINES
Committee Members
• Doug McKim and Jeremy Road : Co-chairs• Nigel Duguid• Debra Morrison• Colleen O’Connell• Francois Maltais• Fabien Cote• Basil Petrof• Monica Avendano, Steve Abdool and Janet Fraser• Robert Skomro• Karen Rimmer• Methodologist Tom Oliver• Observer Ian MacLusky (Paeds)• Admin. Assistance CTS• Not one have a COI with material to be presented .
• Committee formed in 2008
• Evolution of technology • Emerging clinical experience• Care gaps across the country, around the world• Absence of CPG • Significant expense• Ethical issues
EUROVENT STUDY (ERJ , 2005)
• 16 countries• 483 centers• Wide variation in patients on HMV• Invasive v non invasive• “Lung users” < 1 year ; neuromuscular > 6 years
CTS HMV Guidelines: Disease Specific
Eleven of the areas of most significance for those requiring Prolonged Assisted Ventilation (PAV) and addressed by the guidelines were as follows:
• * Airway Clearance in Ventilator Assisted Individuals• * Transition to Home• Amyotrophic Lateral Sclerosis• Central Hypoventilation Syndrome• Stable COPD• Kyphoscoliosis• Obesity Hypoventilation Syndrome• Spinal Cord Injury• Duchenne Muscular Dystrophy• Muscular Dystrophies other than Duchenne and Myopathies• * Ethical Considerations• First CPG on HMV to adapt this process
Methodology
• Guideline development– AGREE II , GRADE/Grading recommendations table from the ACCP
report, Judging the Strength of Recommendations Consensus-building process, external review
• Literature Search Strategy– MEDLINE (OVID: 1980 through June 2010), EMBASE OVID: (1980
through June 2010), HealthStar (1980 through June 2010), the Cochrane Library (OVID; Issue 1, 2009), the Canadian Medical Association InfoBase, and the National Guideline Clearinghouse
• Study selection criteria– outcomes of interest: survival, pulmonary function, sleep parameters,
airway clearance techniques, VAI and caregiver quality of life, transition to home, ethical considerations
Guideline Development Process
• Grading system ( GRADE , Guyatt et al Chest 2006)• Quality of evidence : A,B or C• Strength of recommendations 1 or 2• Consensus building meetings• Established key research questions for the future.• External review process: international experts,
Canadian partners including Spinal Cord Network, ALS and Muscular Dystrophy Societies and CRTS.
External Reviewers Comments
• Strong support for the document• AGREE II scores were high • 2 concerns: procedure for updating guideline and
opinions of patients were not sought• Some wanted more information on “how to”• Some suggestions re : recommendations and levels of
evidence .
Guideline Development Process
• Compendium (source document).
• Executive summary includes– Synopsis of section
– Conclusions
– Recommendations with levels of evidence
Collaboration with LTMV Canadian Community of Excellence Steering Group
• Initial meeting of working group in 2010• CIHR funded program, April 2011. “Understanding
LTMV in Canada: A Programmatic Approach” . PI : Louise Rose.
Dissemination and Implementation
• Publication in 2011• Target groups with shared interest• Collaboration with LTMV group• Research opportunities
Central Hypoventilation Syndrome (CHS)
• Rare condition• Decreased respiratory drive• Varied etiology
Etiology of CHS
Acquired: Brainstem Disease Cerebrovascular accidentTumor or space occupying lesionSyringomyeliaPost poliomyelitisTraumaArnold Chiari malformationCNS infectionNeurodegenerative processes , MSA.
Congenital CHS: PHOX2B mutationsPerry Syndrome Nemaline myopathy
Idiopathic
• In pediatric population 4 retrospective chart reviews (n=6-196)
• In adults mostly case reports on acquired causes of CHS
• In pediatric population with Congenital Central Hypoventilation Syndrome ( CCHS) 90% have the PHOX2B mutation
• Late onset , LO-CCHS in adults can be associated with the PHOX2B mutation as well, less severe than pediatric presentation
• First degree relatives should be screened as carriers can be affected
Recommendations• 1. The diagnosis of CHS is best established by polysomnography
supplemented with transcutaneous CO2 or early morning ABGs. (GRADE 1C)
• 2. Once the diagnosis of CHS is established, it is strongly recommended that acquired causes should be excluded by MRI of the brainstem. (GRADE 1C)
• 3. Patients with CHS and no known cause should undergo genetic screening for the PHOX2B gene mutation. (GRADE 1C)
• 4. For patients confirmed to have PHOX2B mutation, first degree relatives should be screened for hypoventilation. (GRADE 1C)
• 5. CHS patients who require only nocturnal ventilatory support may be managed by NIV with a back up rate or diaphragmatic pacing. (GRADE 1C)
• 6. Severe CHS mainly seen in C-CHS requires continuous ventilatory support but daytime diaphragmatic pacing can markedly improve mobility. (GRADE 1C)
COPD
• RCT ’s of > 3 months duration selected , 7 found.• Clinical practice guidelines from CTS,ATS/ERS and
GOLD consulted• 2 systematic reviews• Outcomes : HRQL, Dyspnea, Exercise Capacity,
Sleep, Hospitalization , Mortality.
Author (Year) Diagnosis Blood Gas NIV
Strumpf, 1991(20)
FEV1 < 1L No pre-established criteria.Mean PaCO2 = 49 (range 35-67)
IPAP = 15EPAP = 2
Meecham Jones, 1995(21)
FEV1 < 50% predicted
PaO2 < 60 mmHGPaCO2 > 45 mmHG
IPAP = 18EPAP = 2
Gay, 1996(14)
FEV1 < 40% predicted
PaCO2 > 45 mmHG IPAP = 10EPAP = 2
Casanova, 2000(15)
FEV1 < 45% predicted
No pre-established criteria Mean PaCO2 = 51 mmHG
IPAP = 12EPAP = 4
Clini, 20021(6)
FEV1 < 1.5L PaCO2 > 50 mmHG IPAP = 14EPAP = 2
Duiverman. 2008(17)
FEV1 < 50% predicted
PaCO2 > 45 mmHG IPAP = 20EPAP = 6
McEvoy, 2009(18)
FEV1 < 1.5L or < 50% predicted
PaCO2 > 46 mmHG IPAP = 13EPAP = 5
Author Year (Ref)
Study Type# of Pts.
Outcomes
DyspneaQuality of life
Exercise capacity
Sleep MortalityHospitalizatio
n
Strumpf, 1991(20)
Randomized, cross-overNIV vs. usual care
23 No change Not assessed
No change No change Not assessed
Not assessed
Meecham Jones, 1995(21)
Randomized, cross-overNIV + LTOT vs. LTOT alone
18 Not assessed
Improved SGRQ symptom scores
No change Improved sleep time and efficiency
Not assessed
Not assessed
Gay, 1996(14)
Randomized, parallel groupNIV vs. sham NIV
13 Not assessed
Not assessed
No change No improvement
Not assessed
Not assessed
Casanova, 2000(15)
Randomized, parallel groupNIV + LTOT vs. LTOT alone
52 Reduced dyspnea
Not assessed
Not assessed
Not assessed
No change No change at 1 year
Clini, 2002(16)
Randomized, parallel groupNIV + LTOT vs. LTOT alone
90 Reduced MRC scores
No change in SGRQ, improved MRF-28
No change No change No change No change
Duiverman, 2008(17)
Randomized, parallel groupNIV + rehabilitation vs. rehabilitation alone
66 No further improvement in CRQ dyspnea subscale with NIV
No further improvement in total CRQ score with NIVLarger improvement in the MRF-28 cognition domain and total score with NIV
No further improvement in exercise capacity with NIV
Not assessed
Not assessed
Not assessed
McEvoy, 2009(18)
Randomized, parallel groupNIV + LTOT vs. LTOT alone
144 Not assessed
No change in SGRQDeterioration in several subscales of the SF-36.
Not assessed
Increased % REM sleep
Improved survival
No change
• Dyspnea- weak evidence• HRQL-conflicting results• Exercise capacity-2 trials showed increase in 6MWD
53 and 13m,one no change• Sleep-conflicting results• Mortality-2 trials no benefit and 1 a benefit (HR 0.63 ,
0.4-0.99)
• Difficult studies to perform ,ill patients with high drop out rates and non adherence to therapy rates of 15-40%.
• In Eurovent study COPD is common indication and use increasing in some countries.
Recommendations• The use of long-term NIV cannot be widely recommended in
patients with stable COPD. (GRADE 1B)• Long-term NIV in COPD should only be considered on an
individual basis. One subgroup of patients with COPD in which long-term NIV could be considered are patients with severe hypercapnia (e.g. PaCO2 greater than 55 mmHG) experiencing repeated episodes of acute hypercapnic respiratory failure that require in-hospital ventilatory support. However, definitive proof of efficacy of long-term NIV in these patients will need to await further studies. (GRADE 2C)
• The overlap syndrome (concomitant COPD and obstructive sleep apnea syndrome) should be differentiated from chronic respiratory failure that is solely due to advanced COPD. (GRADE 1B)
Duchenne Muscular Dystrophy (DMD)
• Studies selected included outcomes of : survival, HRQL, hospitalizations, PFTs and ABGs.
• 11 observational studies (n=10-42)• 8 retrospective chart reviews (n=15-243)• 2 small RCTs (n= 60)
• Absence of dystrophin • Decline in VC 8-12% per year• VC < 40% or MIP < 30 cm H20,at risk for
hypoventilation• Diurnal hypercapnia = high one year mortality and
reduced HRQL• FVC<1L. 5 year survival is 8%.
• Largest RCT Rafael et al (Lancet 1994,343:1600)• Does early NIV improve survival (n= 35 in each arm)• Mortality > in NIV ( 8v2 ) study stopped• Problems : infections managed at home, groups not
controlled for cardiac disease, infrequent follow up and airway clearance techniques were sub optimal.
• Vianello et al (Chest 1994,105:445)• 10 DMD patients with daytime hypercapnia ,followed
for 2 years matched by VC and comorbidity.• 5 refused NIV 4 died, mean survival 9.7 months• NIV group 100 % survived at 2 years
• Danish experience• 243 cases (retrospective chart review)• 1988-2002 vent use increased from 0.9-43%• Mortality rate 3.8 v 9.8% in vent users • 2,4,6 year survival 93,91 and 81% in vent users
• Japanese experience• 157 DMD • Mean age at death 31 yrs in vented group v 20 yrs .
• ABGs improve : from pCO2 60 to 45 mmHg on NIV• HRQL improves
Recommendations for Monitoring• Carefully question and educate patients to report symptoms
consistent with hypoventilation, including disturbed sleep, excessive daytime sleepiness, headache and weight loss. (GRADE 1B)
• Measure VC, MIP, MEP, peak cough flow, and awake oxyhemoglobin saturation by pulse oximetry at least yearly; if VC < 40% predicted, also monitor awake CO2 tension by non-invasive methods or blood gas analysis. (GRADE 1B)
• Perform an evaluation of respiration during sleep if there are symptoms consistent with nocturnal hypoventilation or other forms of sleep-disordered breathing (1B). In the absence of such symptoms, periodic screening for sleep-disordered breathing should also be considered once FEV1 or FVC < 40% predicted. (GRADE 2B)
Recommendations for Treatment
• Offer nocturnal NIV to patients with diurnal hypercapnia (daytime arterial pCO2 > 45 mmHg), or when there is documented nocturnal hypercapnia and the presence of symptoms consistent with hypoventilation. (GRADE 1B)
• Institution of NIV during sleep should also be strongly considered in patients demonstrating a major degree of nocturnal gas exchange disturbance, even if asymptomatic. (GRADE 1C)
• When bilevel ventilation is used, back up respiratory rates are recommended during sleep while on NIV to reduce the work of breathing associated with spontaneous breath initiation (Grade 1C)
• Individualize the decision about the transition from nocturnal NIV to daytime ventilation by carefully evaluating patient factors (symptoms, bulbar involvement, patient preference, etc.) and available resources. In patients requiring daytime ventilation, strongly consider NIV as an alternative to invasive tracheostomy. (GRADE 1B)
• Lung volume recruitment maneuvers should be introduced with declining vital capacity. (see Airway Clearance section) (GRADE 1C)
• Methods to assist secretion clearance should be initiated when peak cough flow is less than 270 l/min. (see Airway Clearance section) (GRADE 1C)
• Thank you