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Heart Failure and VADsHeart Failure and VADsBridges for Broken HeartsBridges for Broken Hearts
Priya Gaiha MD MBAPriya Gaiha MD MBAMay 26May 26thth 2010 2010
University of Kentucky University of Kentucky Grand RoundsGrand Rounds
ObjectivesObjectives
What is the pathophysiology of heart failure?What is the pathophysiology of heart failure?
Why is heart failure relevant?Why is heart failure relevant?
What is the history of mechanical circulatory support?What is the history of mechanical circulatory support?
What are the various types of ventricular assist devices What are the various types of ventricular assist devices (VADs)?(VADs)?
How and when are VADs used?How and when are VADs used?
What is the next generation of VADs?What is the next generation of VADs?
Etiologies of cardiac failureEtiologies of cardiac failure
Coronary artery disease Coronary artery disease Idiopathic cardiomyopathyIdiopathic cardiomyopathy Peripartum cardiomyopathyPeripartum cardiomyopathyDilated cardiomyopathyDilated cardiomyopathyIschemic cardiomyopathyIschemic cardiomyopathyAcute valvular diseaseAcute valvular diseaseArrhythmia (supraventricular or ventricular) Arrhythmia (supraventricular or ventricular) Myocarditis Myocarditis Congenital heart disease Congenital heart disease Drug induced Drug induced Diabetes mellitus Diabetes mellitus Hypertension Hypertension
Pathogenesis of Heart FailurePathogenesis of Heart Failure
Mann, D. Circulation 1999;100;999-1008
NYHA classesNYHA classesClassClass Patient SymptomsPatient Symptoms
Class I (Mild)Class I (Mild) No limitation of physical activity. Ordinary physical No limitation of physical activity. Ordinary physical activity does not cause undue fatigue, palpitation, or activity does not cause undue fatigue, palpitation, or dyspnea (shortness of breath).dyspnea (shortness of breath).
Class II (Mild)Class II (Mild) Slight limitation of physical activity. Comfortable at Slight limitation of physical activity. Comfortable at rest, but ordinary physical activity results in fatigue, rest, but ordinary physical activity results in fatigue, palpitation, or dyspnea.palpitation, or dyspnea.
Class III Class III (Moderate)(Moderate)
Marked limitation of physical activity. Comfortable Marked limitation of physical activity. Comfortable at rest, but less than ordinary activity causes fatigue, at rest, but less than ordinary activity causes fatigue, palpitation, or dyspnea.palpitation, or dyspnea.
Class IV (Severe)Class IV (Severe) Unable to carry out any physical activity without Unable to carry out any physical activity without discomfort. Symptoms of cardiac insufficiency at discomfort. Symptoms of cardiac insufficiency at rest. If any physical activity is undertaken, rest. If any physical activity is undertaken, discomfort is increased.discomfort is increased.
www.americanheart.org
Relevance
NCHS 2006NCHS 2006
2581
242315
5048120
831
21101
138 16585
560
0
200
400
600
800
1,000
<45 45-54 55-64 65-74 75-84 85+ Total
Ages
Dea
ths
in T
ho
usa
nd
s
CVD Cancer
CVD deaths vs. cancer deaths by age (US)CVD deaths vs. cancer deaths by age (US)
A CVD A CVD B CancerB CancerC AccidentsC Accidents
D Chronic Lower Respiratory D Chronic Lower Respiratory DiseasesDiseasesE Diabetes MellitusE Diabetes MellitusF Alzheimer’s DiseaseF Alzheimer’s Disease
NCHS and NHLBI 2006
290,069
59,260
269,819
398,563
78,94136,006
432,709
65,32351,281
42,658
0
100,000
200,000
300,000
400,000
500,000
A B C D E A B D F C
Dea
ths
Males Females
CVD and other major causes of death for all males and females
NHDS/NCHS and NHLBI 2006NHDS/NCHS and NHLBI 2006
1.6
1.7
2.0
2.0
2.4
3.0
3.5
3.5
4.1
6.2
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
Neoplasms 140-239
Endocrine System 240-279
Musculoskeletal System 710-739
Genitourinary System 580-629
Mental 290-319
External: Injuries, etc. 800-999
Respiratory System 460-519
Digestive System 520-579
Obstetrical V27
Cardiovascular 390-459
Hospital Discharges (in millions) for the 10 Leading diagnostic GroupsHospital Discharges (in millions) for the 10 Leading diagnostic Groups
Economic Ramifications
www.americanheart.org
Prevalence 1-2% population 5 million individuals
Cost 1-2% total health care spending
$35 billion
Incidence (per year) 550,000 new diagnoses 300,000 deaths
Hospitalizations 6 days (average) 50% rehospitalized within 6 months
Options for Advanced CHFOptions for Advanced CHF
Transplant ($$$$$$)Transplant ($$$$$$)
Assist Device ($$$)Assist Device ($$$)
Die($)Die($)– Preceded by 6-12 months of medical therapyPreceded by 6-12 months of medical therapy– Multiple hospital re-admissionsMultiple hospital re-admissions– Hospice ($$$)Hospice ($$$)
Transplant
UK
ADULT HEART TRANSPLANTATIONADULT HEART TRANSPLANTATION Kaplan-Meier Survival by Era Kaplan-Meier Survival by Era (Transplants: 1/1982 – 6/2005)(Transplants: 1/1982 – 6/2005)
0
20
40
60
80
100
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
Years
1982-1991 (N=18,844)
1992-2001 (N=34,987)
2002-6/2005 (N=9,459)
All comparisons significant at p < 0.0001
HALF-LIFE 1982-1991: 8.9 years; 1992-2001: 10.3 years; 2002-6/2005: NA
Su
rviv
al (
%)
ISHLT 2007 J Heart Lung Transplant 2007;26: 769-781
ADULT HEART RECIPIENTSADULT HEART RECIPIENTS Functional Status of Surviving RecipientsFunctional Status of Surviving Recipients
(Follow-ups: 1995 - June 2008)(Follow-ups: 1995 - June 2008)
0%
20%
40%
60%
80%
100%
1 Year (N = 16,084) 3 Years (N = 14,221) 5 Years (N = 12,160) 7 Years (N = 9,651)
No Activity Limitations Performs with Some Assistance Requires Total Assistance
ISHLT
2009
Historical EventsHistorical Events
1950 1960 1970 1980 1990 2000 2010
1953: Gibbon’s heart-lung machine successfully used during ASD repair
John GibbonJohn GibbonBorn in 1903 in PhiladelphiaBorn in 1903 in Philadelphia
4th generation physician4th generation physician
1931: watched a young woman 1931: watched a young woman postop from cholecystectomy postop from cholecystectomy die from PEdie from PE
Worked for 20 years on dogs to Worked for 20 years on dogs to refine bypass machinerefine bypass machine
Received financial and technical Received financial and technical support from Thomas Watson support from Thomas Watson of IBMof IBM
1953: first successful use of 1953: first successful use of machine on patient during ASD machine on patient during ASD repairrepair
Historical EventsHistorical Events
1950 1960 1970 1980 1990 2000 2010
1953: Gibbon’s heart-lung machine successfully used during ASD repair
1963: DeBakey implants first VAD in patient with postcardiotomy shock
Historical EventsHistorical Events
1950 1960 1970 1980 1990 2000 2010
1953: Gibbon’s heart-lung machine successfully used during ASD repair
1963: DeBakey implants first VAD in patient with postcardiotomy shock
1967: Barnard performs first heart transplant
Christian Barnard Christian Barnard Born in South Africa in 1922Born in South Africa in 1922
Studied heart surgery at the Studied heart surgery at the University of Minnesota then University of Minnesota then returned to set up a cardiac unit returned to set up a cardiac unit in Cape Town.in Cape Town.
December 1967: transplanted the December 1967: transplanted the heart of a road accident victim heart of a road accident victim into a 59 year old patient into a 59 year old patient
Patient only survived 18 days Patient only survived 18 days due to infectious complicationsdue to infectious complications
Historical EventsHistorical Events
1950 1960 1970 1980 1990 2000 2010
1953: Gibbon’s heart-lung machine successfully used during ASD repair
1963: DeBakey implants first VAD in patient with postcardiotomy shock
1967: Barnard performs first heart transplant
1968: Shumway performs first heart transplant in US
Norm ShumwayNorm Shumway
Stanford UniversityStanford University
1959: transplanted the heart of a 1959: transplanted the heart of a dog into a 2-year-old mongreldog into a 2-year-old mongrel
1968: performed the first heart 1968: performed the first heart transplant in the US on a 54 year transplant in the US on a 54 year old steel worker who lived 14 old steel worker who lived 14 daysdaysPioneered immunosuppressionPioneered immunosuppression1981: performed the world’s 1981: performed the world’s first successful heart-lung first successful heart-lung transplant transplant
Historical EventsHistorical Events
1950 1960 1970 1980 1990 2000 2010
1953: Gibbon’s heart-lung machine successfully used during ASD repair
1963: DeBakey implants first VAD in patient with postcardiotomy shock
1967: Barnard performs first heart transplant
1969: Cooley implants VAD as bridge to transplant
1968: Shumway performs first heart transplant in US
Willem KolffWillem Kolff““Father of artificial organs”Father of artificial organs”1911: Born in the 1911: Born in the NetherlandsNetherlands1940: Established the first 1940: Established the first blood bank in Europe blood bank in Europe 1943: Developed the first 1943: Developed the first artificial kidney artificial kidney 1957: Developed the first 1957: Developed the first artificial heart that was artificial heart that was successfully transplanted successfully transplanted into an animalinto an animal
Historical EventsHistorical Events
1950 1960 1970 1980 1990 2000 2010
1953: Gibbon’s heart-lung machine successfully used during ASD repair
1963: DeBakey implants first VAD in patient with postcardiotomy shock
1984: implantation of Jarvik-7 artificial heart by DeVries
1967: Barnard performs first heart transplant
1969: Cooley implants VAD as bridge to transplant
1968: Shumway performs first heart transplant in US
William DeVriesWilliam DeVriesBorn in 1943Born in 1943Trained at the University of Trained at the University of Utah and Duke UniversityUtah and Duke UniversityWorked with Kolff to Worked with Kolff to implant artificial heart in implant artificial heart in animalsanimals1982: Implanted first 1982: Implanted first artificial heart into Seattle artificial heart into Seattle dentist Barney Clarkdentist Barney Clark1985: Implanted 2nd 1985: Implanted 2nd Jarvik into Bill Schroeder Jarvik into Bill Schroeder in Louisville KYin Louisville KY
Historical EventsHistorical Events
1950 1960 1970 1980 1990 2000 2010
1953: Gibbon’s heart-lung machine successfully used during ASD repair
1963: DeBakey implants first VAD in patient with postcardiotomy shock
1984: implantation of Jarvik-7 artificial heart by DeVries
1994: FDA approval of LVAD as bridge to transplant
1967: Barnard performs first heart transplant
1969: Cooley implants VAD as bridge to transplant
1968: Shumway performs first heart transplant in US
Historical EventsHistorical Events
1950 1960 1970 1980 1990 2000 2010
1953: Gibbon’s heart-lung machine successfully used during ASD repair
1963: DeBakey implants first VAD in patient with postcardiotomy shock
1984: implantation of Jarvik-7 artificial heart by DeVries
1994: FDA approval of LVAD as bridge to transplant
1967: Barnard performs first heart transplant
2004: REMATCH trial1969: Cooley implants VAD as bridge to transplant
1968: Shumway performs first heart transplant in US
Historical EventsHistorical Events
1950 1960 1970 1980 1990 2000 2010
1953: Gibbon’s heart-lung machine successfully used during ASD repair
1963: DeBakey implants first VAD in patient with postcardiotomy shock
1984: implantation of Jarvik-7 artificial heart by DeVries
1994: FDA approval of LVAD as bridge to transplant
1967: Barnard performs first heart transplant
2004: REMATCH trial1969: Cooley implants VAD as bridge to transplant
1968: Shumway performs first heart transplant in US
Heart mate II approved for destination therapy
Criteria for patient selectionCriteria for patient selection
Class IV HFClass IV HFFailing hemodynamicsFailing hemodynamicsPersistent pulmonary edemaPersistent pulmonary edemaNeurologic impairment or renal failure due Neurologic impairment or renal failure due to low perfusionto low perfusionFluid and electrolyte imbalance related to Fluid and electrolyte imbalance related to low cardiac outputlow cardiac outputSevere arrhythmias despite medical Severe arrhythmias despite medical therapy therapy
Indications for supportIndications for support
SBP<80 mm HgSBP<80 mm Hg
MAP<65 mm HgMAP<65 mm Hg
CI<2.0 L/min/mCI<2.0 L/min/m22
PCWP>20 mm HgPCWP>20 mm Hg
SVR>2100 dynes-sec/cmSVR>2100 dynes-sec/cm
Circulation 2005; 112: 438-448
Patient Profile/ Status: INTERMACS Levels
1. Critical cardiogenic shock
2. Progressive decline
3. Stable but inotrope dependent
4. Recurrent advanced HF
5. Exertion intolerant
6. Exertion limited
7. Advanced NYHA III
INTERMACS: Patient Selection
PROFILE-LEVELPROFILE-LEVEL # Pts# Pts
Yr 1Yr 1
Official ShorthandOfficial Shorthand General time frame General time frame for supportfor support
INTERMACSINTERMACS
LEVEL 1LEVEL 1
8282 ““Crash and burn”Crash and burn” HoursHours
INTERMACSINTERMACS
LEVEL 2LEVEL 2
8181 ““Sliding fast”Sliding fast” Days to weekDays to week
INTERMACSINTERMACS
LEVEL 3LEVEL 3
1818 Stable but Stable but DependentDependent
WeeksWeeks
INTERMACSINTERMACS
LEVEL 4LEVEL 4
99 ““Frequent flyer”Frequent flyer” Weeks to few Weeks to few months, if baseline months, if baseline restoredrestored
INTERMACSINTERMACS
LEVEL 5LEVEL 5
44 ““Housebound”Housebound” Weeks to monthsWeeks to months
INTERMACSINTERMACS
LEVEL 6LEVEL 6
33 ““Walking wounded”Walking wounded” Months, if nutrition Months, if nutrition and activity and activity maintainedmaintained
INTERMACSINTERMACS
LEVEL 7LEVEL 7
44 Advanced Class III Advanced Class III
INTERMACS ProfilesINTERMACS Profiles
0
10
20
30
40
50
60
70
80
90
100
1 2 3 4 5 6 7
Inotrope Dependent 2006-2007 data
Short term Device optionsShort term Device options
Bridge to recoveryBridge to decision
IABP
ECMO
Tandem Heart
Impella
AbioMed 5000Centrimag
Circulation 112 (3): 438
Intraaortic Balloon Pump (IABP)Intraaortic Balloon Pump (IABP)Developed in late 1960s Developed in late 1960s
Counterpulsation is synchronized to the EKG or Counterpulsation is synchronized to the EKG or arterial waveformsarterial waveforms
Increase coronary perfusion Increase coronary perfusion
Decrease left ventricular stroke work and Decrease left ventricular stroke work and myocardial oxygen requirementsmyocardial oxygen requirements
Most widely used form of mechanical circulatory Most widely used form of mechanical circulatory supportsupport
Indications for its use includeIndications for its use include
– Failure to wean from cardiopulmonary bypassFailure to wean from cardiopulmonary bypass
– Cardiogenic shock after MICardiogenic shock after MI
– Heart failureHeart failure
– Refractory ventricular arrhythmias with Refractory ventricular arrhythmias with ongoing ischemiaongoing ischemia
Bridge to bridge: ECMOBridge to bridge: ECMOImmediately stabilize circulationImmediately stabilize circulation
Improve end organ perfusionImprove end organ perfusion
Overall survival comparable Overall survival comparable between ECMO + LVAD versus between ECMO + LVAD versus LVAD aloneLVAD alone
Clinical indicators of poor outcome Clinical indicators of poor outcome after ECMO: consider VAD after ECMO: consider VAD implantation carefullyimplantation carefully– Elevated blood lactate levelsElevated blood lactate levels– Elevated LFTsElevated LFTs
Pagani et al. Ann Thorac Surg 2000; 70:1977-85
Case #1Case #157 yo male57 yo maleTransferred to UK for cardiogenic Transferred to UK for cardiogenic shock secondary to heart failureshock secondary to heart failureTaken to cath lab for emergent IABP Taken to cath lab for emergent IABP placement placement – EF<10%EF<10%– Sv02 20sSv02 20s– Maximal inotropic support: 4 pressorsMaximal inotropic support: 4 pressors
Stabilized on VA-ECMOStabilized on VA-ECMOSupported for 7 daysSupported for 7 daysImprovement in hepatic and renal Improvement in hepatic and renal dysfunctiondysfunctionHeartmate II implantedHeartmate II implanted
Centrifugal pumpsCentrifugal pumps
Acute hemodynamic supportAcute hemodynamic supportContinuous flowContinuous flowExtracorporealExtracorporealLV, RV or biventricular LV, RV or biventricular supportsupportWide availabilityWide availabilityEase of useEase of useRelatively low costRelatively low costLimited duration of supportLimited duration of supportBridge to recoveryBridge to recoveryBridge to decisionBridge to decision
Hoy et al. Ann Thorac Surg 2000; 70:1259-63
Tandem hearts Tandem hearts
Acute hemodynamic supportAcute hemodynamic supportCentrifugal pumpCentrifugal pumpPercutaneous placementPercutaneous placementLV support via transseptal LV support via transseptal cannulacannulaUsed in high risk cardiac Used in high risk cardiac catheterization procedurescatheterization proceduresRisk of vascular injuries due to Risk of vascular injuries due to cannula sizecannula size
Levitronix CentrimagLevitronix CentrimagNewer generationNewer generationCentifugal pumpCentifugal pumpContinuous flowContinuous flowExtracorporeal Extracorporeal Impellar within the Impellar within the pump rotates in pump rotates in contact-free mannercontact-free mannerIncreased durabilityIncreased durabilityMinimal thrombus Minimal thrombus formation and formation and hemolysis of RBCshemolysis of RBCs
Abiomed 5000Abiomed 5000
ExtracorporealExtracorporeal
Pneumatic pulsatile pumpsPneumatic pulsatile pumps
Uni- or biventricular Uni- or biventricular supportsupport
Bridge to transplantBridge to transplant
Easy to insert and operate Easy to insert and operate so used in community so used in community hospitalshospitals
Flows 6L/minFlows 6L/min
Circulation. 2005;112:438-448.
Impella Impella Axial flow pumpsAxial flow pumpsAcute hemodynamic Acute hemodynamic supportsupportMiniaturized impellar pump Miniaturized impellar pump in catheterin catheterHelical catheter tip placed Helical catheter tip placed across aortic valve and left across aortic valve and left ventricleventriclePercutaneous or direct Percutaneous or direct placementplacementFlow 4.5L/minFlow 4.5L/minBridge to recoveryBridge to recovery
Case #2Case #2
54 yo male54 yo malePostcardiotomy cardiogenic shock after mitral Postcardiotomy cardiogenic shock after mitral valve repair and CABGx 4v valve repair and CABGx 4v Came off CPB but then decompensatedCame off CPB but then decompensatedInitially treated with Impella placementInitially treated with Impella placementDeveloped hemolysis: converted to Abiomed Developed hemolysis: converted to Abiomed 5000 BVS pump 48hrs later5000 BVS pump 48hrs laterTransferred to UKTransferred to UKSuccessfully explanted after 7 days of supportSuccessfully explanted after 7 days of supportFunctional at home, EF~45%Functional at home, EF~45%
Long term Device optionsLong term Device options
Bridge to transplant
Heartmate II
Jarvik 2000 CardioWest TAH
Heartmate XVE
Circulation 112 (3): 438
Thoratec
Thoratec Thoratec Pneumatic pumpPneumatic pump
LVAD, RVAD or LVAD, RVAD or biventricular supportbiventricular support
DurableDurableCan be used in smaller Can be used in smaller
patientspatientsFlows 7L/minFlows 7L/minBridge to recoveryBridge to recoveryBridge to transplantBridge to transplant
Circulation. 2005;112:438-448.
Case #3Case #3
31 yo male31 yo male Severe end-stage heart failure secondary Severe end-stage heart failure secondary
to idiopathic cardiomyopathyto idiopathic cardiomyopathy Symptoms refractory to medical Symptoms refractory to medical
managementmanagement Biventricular Thoratec device implanted Biventricular Thoratec device implanted
along with closure of PFO and removal of along with closure of PFO and removal of LV apical thrombusLV apical thrombus
Duration of device 96 daysDuration of device 96 days Developed thrombus in inflow cannulaDeveloped thrombus in inflow cannula
– Upgraded status on UNOS waiting listUpgraded status on UNOS waiting list Orthotopic heart transplant performedOrthotopic heart transplant performed Discharged POD#13Discharged POD#13 Doing well with no evidence of rejection Doing well with no evidence of rejection
Long term Device optionsLong term Device options
Bridge to transplant Destination therapy
Heartmate IIHeartmate XVE
Heartmate XVEHeartmate XVE
Pneumatic or vented electric Pneumatic or vented electric platesplates
Textured internal surfacesTextured internal surfaces Only left-sided supportOnly left-sided support Flows 10L/minFlows 10L/min Bridge to transplantBridge to transplant First device to be approved First device to be approved
for destination therapyfor destination therapy Need BSA>1.5Need BSA>1.5 Limited durability: half life 18 Limited durability: half life 18
monthsmonths Infection risk with Infection risk with
percutaneous drive linepercutaneous drive line
Circulation. 2005;112:438-448.
Case #4Case #4 58 yo male58 yo male Ischemic cardiomyopathy after MIIschemic cardiomyopathy after MI Symptoms progressively refractory to medical Symptoms progressively refractory to medical
therapytherapy– EF <20%EF <20%– Required intermittent inotropic supportRequired intermittent inotropic support
BMI >40: VAD versus transplantBMI >40: VAD versus transplant Heartmate XVE implantedHeartmate XVE implanted Device began to fail after 18 months Device began to fail after 18 months Heartmate II Heartmate II
implantedimplanted Continues with daily activitiesContinues with daily activities VAD as destination therapyVAD as destination therapy
Heartmate IIHeartmate II
Axial flow Axial flow LV supportLV supportFlows 10L/minFlows 10L/minLong term durabilityLong term durabilityBridge to transplantBridge to transplantApproved January 2010 Approved January 2010
for destination therapyfor destination therapyOver 4000 devices Over 4000 devices
implanted to dateimplanted to date
Case #5Case #5 64 yo male64 yo male Ischemic cardiomyopathy due to large anterolateral MI since 1982Ischemic cardiomyopathy due to large anterolateral MI since 1982 Medical management worked until clinical decompensation in 2008Medical management worked until clinical decompensation in 2008
– Inotropic supportInotropic support– SV02 in 20sSV02 in 20s
Not a favorable transplant candidate:Not a favorable transplant candidate:– Severe pulmonary hypertension: PAP >70-80sSevere pulmonary hypertension: PAP >70-80s– High PVR > 5 Wood unitsHigh PVR > 5 Wood units– MalnutritionMalnutrition– multiorgan system failure: hepatic, renalmultiorgan system failure: hepatic, renal
Heartmate II implantedHeartmate II implanted Improvement in pulmonary hypertension, renal dysfunction and Improvement in pulmonary hypertension, renal dysfunction and
nutritional statusnutritional status Duration of therapy 9 monthsDuration of therapy 9 months Orthotopic transplant successful August 2009Orthotopic transplant successful August 2009
Implantation of deviceImplantation of device
N Engl J Med 2007;357:885-N Engl J Med 2007;357:885-9696
Implantation Implantation
Implantation Implantation
Implantation Implantation
Implantation Implantation
Implantation Implantation
Implantation Implantation
Implantation Implantation
Implantation Implantation
Device complicationsDevice complications
EarlyEarly– BleedingBleeding– Right sided heart failureRight sided heart failure– Progressive multiorgan system failureProgressive multiorgan system failure
LateLate– InfectionInfection
NosocomialNosocomialDevice relatedDevice related
– ThromboembolismThromboembolism– Failure of deviceFailure of device
Next generation of VADsNext generation of VADs
Miniaturized Miniaturized Improved durabilityImproved durability
– Bearing-less technologyBearing-less technology
Blood compatible surfacesBlood compatible surfaces– NonthrombogenicNonthrombogenic
Transcutaneous Transcutaneous – Drive line Drive line – Power sourcesPower sources
Thank you.
Additional slidesAdditional slides
Cellular benefits of VADsCellular benefits of VADs
Normalization of fiber orientationNormalization of fiber orientationRegression of myocyte hypertrophyRegression of myocyte hypertrophyReduction in contraction band necrosisReduction in contraction band necrosisReverse ventricular dilationReverse ventricular dilation
– Improvement in EDPVRImprovement in EDPVR
Improved efficiency of myocardial mitochondriaImproved efficiency of myocardial mitochondriaReduction in abnormalities along neurohormonal Reduction in abnormalities along neurohormonal
and cytokine pathwaysand cytokine pathways
Circulation. 1998;98:2367-2369.
Indicators of poor clinical Indicators of poor clinical outcomeoutcome
Advanced ageAdvanced age– Independent predictor of poor survivalIndependent predictor of poor survival– Independent predictor of poor bridge to transplantIndependent predictor of poor bridge to transplant– 37% post 30-day LVAD mortality37% post 30-day LVAD mortality– Age limit? >65 yo contraindication to transplantAge limit? >65 yo contraindication to transplant
FemaleFemale– Independent predictor of poor survivalIndependent predictor of poor survival– Independent predictor of poor bridge to transplantIndependent predictor of poor bridge to transplant– Higher mortalityHigher mortality
Longer waiting time to transplant due to size criteriaLonger waiting time to transplant due to size criteria
– Increased operative mortalityIncreased operative mortalitySmaller BSASmaller BSAImpaired wound healingImpaired wound healing
JCTS 2005:130;5: 1302-1311
Indicators of poor clinical Indicators of poor clinical outcomeoutcome
Diabetes mellitusDiabetes mellitus– 4-fold increased risk of early death4-fold increased risk of early death– Associated with end organ failureAssociated with end organ failure
Renal failureRenal failure
– Increased allograft vasculopathy after transplantIncreased allograft vasculopathy after transplant– Type I DM is contraindication to transplantType I DM is contraindication to transplant
Low preoperative serum albuminLow preoperative serum albumin– Surrogate measure of nutritional statusSurrogate measure of nutritional status– Increased infections and impaired wound healingIncreased infections and impaired wound healing– For every 1 mg/dL increase in albumin, had 19.2 times For every 1 mg/dL increase in albumin, had 19.2 times
increased likelihood for bridge to transplantincreased likelihood for bridge to transplant
JCTS 2005:130;5: 1302-1311
Myocardial recoveryMyocardial recovery
Certain proportion of Certain proportion of idiopathic dilated idiopathic dilated cardiomyopathy patients cardiomyopathy patients have potential for have potential for complete cardiac complete cardiac recovery: 15-20%recovery: 15-20%– Younger ageYounger age– Shorter history of heart Shorter history of heart
failurefailure– Faster and more complete Faster and more complete
restoration of pump functionrestoration of pump function– Diminished fibrosis seen in Diminished fibrosis seen in
myocyte biopsiesmyocyte biopsies Ann Thorac Surg 2001; 71:S109-13
Myocardial recoveryMyocardial recoveryDisease statesDisease states
– Fulminant myocarditisFulminant myocarditis– Postcardiotomy shockPostcardiotomy shock
Improvements in pathophysiologyImprovements in pathophysiology– Normalization in circulating neurohormonal Normalization in circulating neurohormonal
and cytokine levelsand cytokine levels Improvements in LV: “reverse Improvements in LV: “reverse
remodeling”remodeling”– Regression of LV hypertrophyRegression of LV hypertrophy– Normalization of LV volume-pressure curvesNormalization of LV volume-pressure curves
Myocardial recoveryMyocardial recovery
Circulation 2005;112;I-32-I-36
EF
White: ischemic
Gray: nonischemic, maintained recovery
Striped: nonischemic
Parameters to predict recoveryParameters to predict recovery
EchoEcho– Decreased LV diameterDecreased LV diameter– Improved EF (>40%)Improved EF (>40%)
HistologyHistology– Resolution of myocyte fibrosis and necrosisResolution of myocyte fibrosis and necrosis
HemodynamicsHemodynamics– Decreased PCWPDecreased PCWP– Decreased PVRDecreased PVR– Improved peak oxygen exercise consumptionImproved peak oxygen exercise consumption