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Nutritional Management of Hepatic Encephalopathy

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Title: Nutritional Management of Hepatic Encephalopathy


1
Nutritional Management of Hepatic Encephalopathy
  • Presented by
  • Chris Theberge Sara Murkowski

2
Presentation At A Glance
  • Background on Liver Dysfunction
  • Review of liver physiology
  • Diseases of the liver
  • Development of Hepatic Encephalopathy
  • Pathogenesis Theories
  • Incidence, Prognosis, Diagnostic Criteria
  • Clinical manifestations, Nutritional
    manifestations
  • Treatment Medical Management
  • Case Study
  • Nutritional Management
  • Historical Treatment Theories/Practice
  • Protein Restriction BCAA Supplementation
  • Goals of MNT

3
Lets Take It From The Top
  • A Physiology Review

4
Functions of the LiverA Brief Overview
  • Largest organ in body, integral to most metabolic
    functions of body, performing over 500 tasks
  • Only 10-20 of functioning liver is required to
    sustain life
  • Removal of liver will result in death within 24
    hours

5
Functions of the Liver
  • Main functions include
  • Metabolism of CHO, protein, fat
  • Storage/activation vitamins and minerals
  • Formation/excretion of bile
  • Steroid metabolism, detoxifier of drugs/alcohol
  • Action as (bacteria) filter and fluid chamber
  • Conversion of ammonia to urea
  • Gastrointestinal tract significant source of
    ammonia
  • Generated from ingested protein substances that
    are deaminated by colonic bacteria
  • Ammonia enters circulation via portal vein
  • Converted to urea by liver for excretion

6
Aspartate Transaminase(AST)
The Urea Cycle
Alanine Transaminase (ALT)
7
Liver Diseases
Classifications
  • Duration
  • Acute vs Chronic
  • Pathophysiology
  • Hepatocellular vs Cholestasic
  • Etiology
  • Viral
  • Alcohol
  • Toxin
  • Autoimmune
  • Stage/Severity
  • ESLD
  • Cirrhosis
  • Viral hepatitis A, B, C, D, E (and G)
  • Fulminant hepatitis
  • Alcoholic liver disease
  • Non-alcoholic liver disease
  • Cholestatic liver disease
  • Hepatocellular carcinoma
  • Inherited disorders

8
Liver Diseases
  • Fulminant Hepatic Failure (Shocked Liver)
  • Rapid, severe acute liver injury with impaired
    function and encephalopathy in someone with a
    previously normal liver or with well-compensated
    liver disease
  • Encephalopathy within 8 weeks of symptom onset or
    within 2 wks of developing jaundice
  • Multiple causes (ie, drug toxicity, hepatitis)
  • Malnutrition often not major issue
  • Chronic Hepatic Failure (Subfulminant" Hepatic
    Failure)
  • At least 6-month course of hepatitis or
    biochemical and clinical evidence of liver
    disease with confirmatory biopsy findings of
    unresolving hepatic inflammation
  • Multiple causes autoimmune, viral, metabolic,
    toxic

9
Liver Diseases
  • Cholestatic Liver Diseases
  • Primary biliary cirrhosis (PBC)
  • Immune-mediated chronic cirrhosis of the liver
    due to obstruction or infection of the small and
    intermediate-sized intrahepatic bile ducts
  • 90 of patients are women
  • Nutritional complications
  • Osteopenia, hypercholesterolemia, fat-soluble
    vitamin deficiencies
  • Sclerosing cholangitis
  • Fibrosing inflammation of segments of
    extrahepatic bile ducts, with or without
    involvement of intrahepatic ducts
  • Nutritional complications
  • Inflammatory bowel disease, fat soluble vitamin
    deficiencies, hepatic osteodystrophy
    (steatorrhea)

10
Inherited Liver Disorders
  • Hemochromatosis
  • Inherited disease of iron overload
  • Wilsons disease
  • Autosomal recessive disorder associated with
    impaired biliary copper excretion
  • a1-antitrypsin deficiency
  • Causes cholestasis or cirrhosis and can cause
    liver and lung cancer

11
Liver Diseases
  • Alcoholic Liver Disease, Alcoholic hepatitis, and
    Cirrhosis
  • Diseases resulting from excessive alcohol
    ingestion characterized by fatty liver (hepatic
    steatosis), hepatitis, or cirrhosis (fibrous
    tissue)
  • Prognosis depends on degree of abstinence and
    degree of complications
  • Malnutrition often an issue in these patients
  • Most common liver disease in US

12
Progression of Liver Diseases
13
Normal Liver
14
Alcoholic Fatty Liver
15
Cirrhotic Liver
16
Prognosis of Cirrhosis
Child-Pugh and MELD Score Both used to determine
prognosis of Cirrhosis (mortality and
survival) Determine Need For Transplantation Use
d in studies to determine effect of treatment on
liver function
17
Malnutrition In Liver Disease
  • Malnutrition is an early and typical aspect of
    hepatic cirrhosis
  • Contributes to poor prognosis and complications
  • Degree of malnutrition related to severity of
    liver dysfunction and disease etiology (higher in
    alcoholics)
  • Mortality doubled in cirrhotic patients with
    malnutrition (35 vs 16)
  • Complications more frequent than in
    well-nourished (44 vs 24)
  • Usually more of a clinical problem than hepatic
    encephalopathy itself

18
Cirrhosis is common end result of many chronic
liver disorders
  • Severe damage to structure function of normal
    cells
  • Inhibits normal blood flow
  • Decrease in functional hepatocytes
  • Results in portal hypertension ascites
  • Portal systemic shunting
  • Blood bypasses the liver via shunt, thus
    bypassing detoxification
  • Toxins remain in circulating blood
  • Neurtoxic substances can precipitate hepatic
    encephalopathy

19
And Now Our Featured Presentation
20
What is Hepatic Encephalopathy?
  • Broadly defined
  • All neurological and psychological symptoms in
    patients with liver disease that cannot be
    explained by presence of other pathologies
  • Brain and nervous system damage secondary to
    severe liver dysfunction (most often chronic
    disease) resulting from failure of liver to
    remove toxins
  • Multifactorial pathogenesis with exact cause
    unknown
  • Symptoms vary from nearly undetectable, to coma
    with decerebration
  • Characterized by various neurologic symptoms
  • Cognitive impairment
  • Neuromuscular disturbance
  • Altered consciousness
  • Reversible syndrome

21
Incidence Prognosis
  • Incidence
  • 10-50 of cirrhotic pts and portal-systemic
    shunts (TIPS) experience episode of overt hepatic
    encephalopathy
  • True incidence/prevalence of HE unknown
  • Lack of definitive diagnosis
  • Wide spectrum of disease severity
  • Prognosis
  • 40 survival rate 1 year following first episode
  • 15 survival rate 3 years following first episode

22
Clinical Manifestations of HE
  • Cerebral edema
  • Brain herniation
  • Progressive, irreversible coma
  • Permanent neurologic losses (movement, sensation,
    or mental state)
  • Increased risk of
  • Sepsis
  • Respiratory failure
  • Cardiovascular collapse
  • Kidney Failure

23
Variants of Hepatic Encephalopathy
  • Acute HE
  • Associated with marked cerebral edema seen in
    patients with the acute onset of hepatic failure
    (FHF)
  • Hormonal disarray, hypokalemia, vasodilation (ie,
    vasopressin release)
  • Quick progression coma, seizures, and
    decerebrate rigidity
  • Altered mental function attributed to increased
    permeability of the blood-brain barrier and
    impaired brain osmoregulation
  • Results in brain cell swelling and brain edema
  • Can occur in cirrhosis, but usually triggered by
    precipitating factor
  • Precipitating factors usually determine outcome

24
Precipitants of Hepatic Encephalopathy
  • Portosystemic Shunting
  • Radiographic or surgically placed shunts
  • Spontaneous shunts
  • Vascular Occlusion
  • Portal or Hepatic Vein Thrombosis
  • Drugs
  • Benzodiazepines
  • Narcotics
  • Alcohol
  • Dehydration
  • Vomiting
  • Diarrhea
  • Hemorrhage
  • Diuretics
  • Large volume paracentesis
  • Increased Ammonia Production,
  • Absorption or Entry Into the Brain
  • Excess Dietary Intake of Protein
  • GI Bleeding
  • Infection
  • Electrolyte Disturbances (ie., hypokalemia)
  • Constipation
  • Metabolic alkalosis

Primary Hepatocellular Carcinoma
25
Variants of Hepatic Encephalopathy
  • Chronic HE
  • Occurs in subjects with chronic liver disease
    such as cirrhosis and portosystemic shunting of
    blood (Portal Systemic Encepalopathy PSA)
  • Characterized by persistence of neuropsychiatric
    symptoms despite adequate medical therapy.
  • Brain edema is rarely reported
  • Refractory HE
  • Recurrent episodes of an altered mental state in
    absence of precipitating factors
  • Persistent HE
  • Progressive, irreversible neurologic findings
    dementia, extrapyramidal manifestations,
    cerebellar degeneration, transverse cordal
    myelopathy, and peripheral neuropathy
  • Subclinical or Minimal HE
  • Most frequent neurological disturbance
  • Not associated with overt neuropsychiatric
    symptoms
  • Subtle changes detected by special psychomotor
    tests

26
Stages of Hepatic Encephalophay
Stage Symptoms
I Mild Confusion, agitation, irritability, sleep disturbance, decreased attention
II Lethargy, disorientation, inappropriate behavior, drowsiness
III Somnolent but arousable, slurred speech, confused, aggressive
IV Coma
27
Pathogenesis Theories
  • Endogenous Neurotoxins
  • Ammonia
  • Mercaptans
  • Phenols
  • Short-medium fatty acids
  • Increased Permeability of Blood-Brain Barrier
  • Change in Neurotransmitters and Receptors
  • GABA
  • Altered BCAA/AAA ratio
  • Other
  • Zinc defficiency
  • Manganese deposits

28
Neurotoxic Action of Ammonia
  • Readily crosses blood-brain barrier
  • Increased NH3 increased glutamate
  • a-ketoglutarateNH3NADH?glutamateNAD
  • glutamateNH3ATP?glutamineADPPi
  • As a-ketoglutarate is depleted TCA cycle activity
    halted
  • Increased glutamine formation depletes glutamate
    stores which are needed by neural tissue
  • Irrepairable cell damage and neural cell death
    ensue.
  • In liver disease, conversion of ammonia to urea
    and glutamine can be reduced up to 80

29
Pathogenesis Theories False Neurotransmitter
Hypothesis
  • Liver cirrhosis characterized by altered amino
    acid metabolism
  • Increased Aromatic Amino Acids in plasma and
    influx in brain
  • Decrease in plasma Branched Chain Amino Acids
  • Share a common carrier at blood-brain barrier
  • BCAAs in blood may result in AAA
    transport to brain

30
Abnormal plasma amino acidschronic liver disease
400
Glu
350
Phe
Asp
300
Meth
250
Tyr
of Normal
200
Try
150
Gly
100
Orn
Thr
Ser
Lys
Tau
His
Val
50
Leu
Arg
Pro
Ala
Ileu
Essential
Non-Essential
Cerra, et al JPEN, 1985
J. Y. Pang
31
Pathogenesis Theories False Neurotransmitter
Hypothesis
  • AAA are precursors to neurotransmitters and
    elevated levels result in shunting to secondary
    pathways

32
Pathogenesis TheoriesChange In
Neurotransmitters and Receptors
  • Gamma-Aminobutyric Acid (GABA)
  • BCAA-Ammonia Connection

33
Increase Permeability of Blood-Brain Barrier
  • Astrocyte (glial cell) volume is controlled by
    intracellular organic osmolyte
  • Organic osmolyte is glutamine.
  • glutamine levels in the brain result in
    volume of fluid within astrocytes resulting in
    cerebral edema (enlarged glial cells)
  • Neurological impairment
  • NNormal Astrocytes
  • AAlzheimer type II astrocytes
  • Pale, enlarged nuclei
  • characterisic of HE

34
Symptoms of HE
  • Changes in mental state, consciousness
  • Confusion, disorientation
  • Delirium
  • Dementia (loss of memory, intellect)
  • Mood swings
  • Decreased altertness, responsiveness
  • Coma
  • Course muscle tremors
  • Muscle stiffness or rigidity
  • Loss of small hand movements (handwriting)
  • Seizures (rare)
  • Decreased self-care ability
  • Speech impairment

35
Diagnosing HE
  • No single laboratory test is sufficient to
    establish the diagnosis
  • No Gold Standard
  • Pt brains cannot be studied with
    neurochemical/neurophysiologic methods
  • Data on cerebral function in HE usually derived
    from animal studies
  • Underlying cause of liver disease itself may be
    associated with neurologic manifestations
  • Alcoholic liver disease (Wernickes)

36
Diagnostic Criteria
  • Asterixis (flapping tremor)
  • Hx liver disease
  • Impaired performance on neuropsychological tests
  • Visual, sensory, brainstem auditory evoked
    potentials
  • Sleep disturbances
  • Fetor Hepaticus
  • Slowing of brain waves on EEG
  • PET scan
  • Changes of neurotransmission, astrocyte function
  • Elevated serum NH3
  • Stored blood contains 30ug/L ammonia
  • Elevated levels seen in 90 pts with HE
  • Not needed for diagnosis

37
Differential Diagnosis
  • Metabolic encephalopathiesDiabetes
    (hypoglycemia, ketoacidosis)HypoxiaCarbon
    dioxide narcosis
  • Toxic encephalopathiesAlcohol (acute alcohol
    intoxication, delirium tremens,
    Wernicke-Korsakoff syndrome)Drugs
  • Intracranial eventsIntracerebral bleeding or
    infarctionTumorInfections (abscess,
    meningitis)Encephalitis

38
Treatment of Hepatic Encephalopathy
  • Various measures in current treatment of HE
  • Strategies to lower ammonia production/absorption
  • Nutritional management
  • Protein restriction
  • BCAA supplementation
  • Medical management
  • Medications to counteract ammonias effect on
    brain cell function
  • Lactulose
  • Antibiotics
  • Devices to compensate for liver dysfunction
  • Liver transplantation

39
  • Proposed
  • Complex
  • Feedback
  • Mechanisms
  • In Treatment
  • Of HE

40
Nutritional Management of HE
  • Historical treatment theories
  • Protein Restriction
  • BCAA supplementation
  • Goals of MNT
  • Treatment of PCM associated with ESLD

41
Historical Treatment TheoriesProtein Restriction
  • Studies in early 1950s showed cirrhotic pts
    given nitrogenous substances developed hepatic
    precoma
  • Led to introduction of protein restriction
  • Began with 20-40g protein/day
  • Increased by 10g increments q3-5 days as
    tolerated with clinical recovery
  • Upper limit of 0.8-1.0 g/kg
  • Was thought sufficient to achieve positive
    nitrogen balance
  • Lack of Valid Evidence
  • Efficacy of restriction never proven within
    controlled trial

42
Dispelling the Myth
  • Normal Protein Diet for Episodic Hepatic
    Encephalopathy
  • Cordoba et al. J Hepatol 2004 41 38-43
  • Objective To test safety of normal-protein diets
  • Randomized, controlled trial in 20 cirrhotic
    patients with HE
  • 10 patients subjected to protein restriction,
    followed by progressive increments
  • No protein first 3 days, increasing q3days until
    1.2g/kg daily for last 2 days
  • 10 patients followed normal protein diet
    (1.2g/kg)
  • Both groups received equal calories

43
Dispelling the Myth
  • Results
  • On days 2 and 14
  • Similar protein synthesis among both groups
  • Protein breakdown higher in low-protein group
  • Conclusion
  • No significant differences in course of hepatic
    encephalopathy
  • Greater protein breakdown in protein-restricted
    subjects

44
Protein and HE Considerations
  • Presence of malnutrition in pts with cirrhosis
    and ESLD clearly established
  • No valid clinical evidence supporting protein
    restriction in pts with acute HE
  • Higher protein intake required in CHE to maintain
    positive nitrogen balance
  • Protein intake lt 40g/day contributes to
    malnutrition and worsening HE
  • Increased endogenous protein breakdown NH3
  • Susceptibiliy to infection increases under such
    catabolic conditions

45
Other Considerations
  • Vegetable Protein
  • Beneficial in patients with protein intolerance
    lt1g/kg
  • Considered to improve nitrogen balance without
    worsening HE
  • Beneficial effect d/t high fiber content
  • Also elevated calorie-to-nitrogen ratio
  • BCAA Supplementation
  • Effective or Not?

46
Branched Chain Amino Acids (BCAA)
Valine Leucine Isoleucine
  • Important fuel sources for skeletal muscle during
    periods of metabolic stress
  • Metabolized in muscle brain, not
  • liver
  • -promote protein synthesis
  • -suppress protein catabolism
  • -substrates for gluconeogenesis
  • Catabolized to L-alanine and L-glutamine in
    skeletal muscle

47
  • Nutritional Supplementation with Branched-Chain
    Amino Acids in Advanced Cirrhosis A
    Double-Blind, Randomized Trial
  • Marchesini et al.,(2004). Gastroenterology, 124,
    1792-1801

48
Nutritional Supplementation with Branched-Chain
Amino Acids in Advanced Cirrhosis A
Double-Blind, Randomized Trial
  • Multi-Center, randomized, controlled study
    involving 15 centers with interest in patients
    with liver disease
  • Inclusion Criteria
  • A diagnosis of liver cirrhosis documented by
    histology and confirmed lab data
  • Child-Pugh score 7 (Class B or C)
  • Sonographic and endoscopic evidence of portal
    hypertension
  • Exclusion Criteria
  • Active alcohol consumption, overt HE, refractory
    ascites, reduced renal function (Cre 1.5
    mg/dL), Child-Pugh score 12, suspected
    hepatocellular carcinoma, previous poor
    compliance to pharmacological treatment of
    nutrition counseling

49
Nutritional Supplementation with Branched-Chain
Amino Acids in Advanced Cirrhosis A
Double-Blind, Randomized Trial
  • Primary Outcomes
  • Combined survival and maintenance of liver
    function, as assessed by death (any reason),
    deterioration to exclusion criteria, or
    transplant
  • Number of hospital admissions
  • Duration of hospital stay
  • Secondary Outcomes
  • Nutritional parameters and liver function tests
    (Child-Pugh scores)
  • Anorexia and health-related quality of life
  • Therapy needs

50
Study Profile of BCAA Trial BCAA Lactoalbumin Maltodextrin

Total number 59 56 59
Lost to follow-up 1
Intention-to-treat analysis 58 56 59
Events (death, any cause, or progression of liver failure to exclusion criteria) 9 (15.5) 18 (32.1) 16 (27.1)
Removed from systematic follow-up1 7 4 4
    Development of HCC2 1 1 2
    Noncompliance to treatment3 5 (1) 2 (1) 0
    Side effects3 44 (1) 2 (1) 2
    Treatment-unrelated diseases 1
Regular 3-mo follow-up 42 (71.2) 34 (60.7) 39 (66.1)
    Admission to hospital 15 (35.7) 27 (79.4) 28 (71.8)
    Admission rate (patients/y) 0.6 0.2 2.1 0.5 1.9 0.4
    Total no. d in hospital 195 327 520
Significantly different from both lactoalbumin
and maltodextrin. 1 Some individuals were
removed based on more than 1 criterion. 2 Cases
with HCC were censored at the time of HCC
diagnosis. 3 The number of withdrawn patients
who died or progressed to exclusion criteria
within 12 mo from entry into the study is
reported in parentheses. 4 Including the patient
lost to follow-up.
51
Primary Outcome Results
  • Based on ITT, time course of events was not
    different between groups (p0.101)
  • A benefit of BCAA only found when non-liver
    disease-related events excluded from analyses
    compared to L-ALB
  • BCAA significantly reduced the combined event
    rates compared with L-ALB, but not with M-DXT
  • L-ALB-OR, 0.43 95 CI (0.19-0.96) p0.039
  • M-DXT-OR, 0.51 95 CI (0.23-1.17) p0.108
  • Less frequent hospital admissions with BCAA vs
    two control arms (p 0.021)

52
  • Secondary Outcomes
  • Nutritional Parameters
  • No change in serum albumin among groups
  • Significant interaction between BCAA and M-DXT
  • Significant reduction in prevalence and severity
    of ascites in BCAA vs controls
  • No significant improvement in HE based on Reitan
    Test)
  • Trend for superiority of BCAA over M-DXT
    (p0.108)

53
Anorexia and Health-Related Quality of Life
  • Increased hunger/satiety in BCAA (p0.019), while
    no change in L-ALB and M-DXT (p0.026)
  • Prevalence of anorexia significantly (p0.0014)
    decreased in BCAA, while unchanged in controls
  • Significant improvement in physical functioning
    in BCAA, while no change in controls
  • Trend (p0.069) towards better scoring of health
    in subjects with BCAA only
  • After 1 year, the percentage of subjects who felt
    their health improved increased (29 to 52) and
    who felt it had worsened decreased (43 to 18)
    (p0.001)

54
Conclusions
  • Long-term BCAA supplementation showed an
    advantage compared to equicaloric,
    equinitrogenous supplemenation
  • Prevention of combined death
  • Progressive liver failure
  • Hospital rates
  • Secondary Outcomes

55
The Mother of All BCAA Trials?Randomized Study
Limitations
  • Poor subject compliance and adverse reactions 3
    times more common in BCAA (15) arm compared to
    controls (5 combined) resulting in greater
    withdrawal
  • Ascertainment bias for event rates
  • Only 115 of 174 subjects had regular f/u at end
    of study, reducing power
  • May explain lack no difference in time course of
    events
  • A benefit of BCAA supplementation only found when
    non-liver-related deaths were excluded from
    analysis
  • Mortality was lower, but BCAA group had similar
    number of deaths compared to the other groups
  • Mean admission rate lower in BCAA compared to
    controls
  • No cost-effectiveness analysis done
  • Reasons for hospital admission?

56
The Mother of All BCAA Trials?Further Study
Limitations
  • No differences in encephalopathy test scores,
    including Reitan testing seen among treatment
    groups, but significant improvement in
    nutritional status in BCAA compared to others
  • Most likely this attributed to reduced admission
    rates

57
  • Branched-Chain Amino Acids For Hepatic
    Encephalopathy
  • Als-Nielsen B, Koretz RI, Kjaergard LL, Gluud C.
    The Cochrane Database of Systematic Reviews,
    2003, 1-55

58
Branched-Chain Amino Acids For Hepatic
Encephalopathy
  • Meta-Analysis of randomized-controlled trials on
    the treatment of HE with IV or oral BCAA
  • Objective
  • To evaluate the beneficial and harmful effects of
    BCAA or BCAA-enriched interventions for patients
    with hepatic encepalopathy
  • Review Criteria
  • All randomized trials included, irrespective of
    blinding, publication status, or language
  • Data from first period of crossover trials and
    unpublished trials included if methodology and
    data accessible
  • Excluded trials in which patients allocated by
    quasi-random method
  • Participants
  • Patients with HE in connection with acute or
    chronic liver disease or FHF
  • Patients of either gender, any age and ethnicity
    included irrespective of etiology of liver
    disease or precipitating factors of HE

59
Branched-Chain Amino Acids For Hepatic
Encephalopathy
  • Types of Interventions
  • Experimental Group
  • BCAA or BCAA-enriched solutions given in any
    mode, dose, or duration with or without other
    nutritive sources
  • Control Group
  • No nutritional support, placebo support,
    isocaloric support, isonitrogenous support, or
    other interventions with a potential effect on HE
    (ie., lactulose)
  • Outcome Measures
  • Primary
  • Improvement of HE (number of patients improving
    from HE using definitions of individual trials)
  • Secondary
  • Time to improvement of HE (number of hours/days
    with HE from the time of randomization to
    improvement)
  • Survival (number of patients surviving at end of
    treatment and at max f/up according to trial)
  • Adverse events (number and types of events
    defined as any untoward medical occurrence in a
    patient, not necessarily causal with treatment)

60
Branched-Chain Amino Acids For Hepatic
Encephalopathy
  • Data Collection and Analysis
  • Trial inclusion and data extraction made
    independently by two reviewers
  • Statistical heterogeneity tested using random
    effects and fixed effect models
  • Binary outcomes reported as risk ratios (RR)
    based on random effects model

61
Branched-Chain Amino Acids For Hepatic
Encephalopathy Results
  • Eleven randomized trials (556 patients)
  • Trial types BCAA versus carbohydrates,
    neomycin/lactulose, or isonitrogenous controls
  • Median number of patients in each trial 55
    (range 22 to 75)
  • Follow-up after treatment reported in 4 trials
  • Median 17 days (range 6 to 30 days)
  • Compared to control regimens, BCAA significantly
    increased the number of patients improving from
    HE at end of treatment
  • RR 1.31, 95 CI 1.04 to 1.66, 9 trials
  • No evidence of an effect of BCAA on survival
  • RR 1.06, 95 CI 0.98 to 1.14, 8 trials
  • No adverse events (RR 0.97, 95 CI 0.41 to 2.31,
    3 trials)

62
Significant
63
Not significant
Combining survival data regardless of window of
f/u showed no significant Difference in survival
between BCAA and controls
64
Branched-Chain Amino Acids For Hepatic
Encephalopathy Results
  • Sensitivity Analyses
  • Methodological quality had a significant impact
    on results
  • Higher quality vs lower quality
  • In trials with adequate generation of allocation
    sequence, allocation concealment, and adequate
    double-blinding, BCAA had no significant effect
    on improvement or survival
  • In trials with unclear generation of allocation
    sequence, allocation concealment, and inadequate
    double-blinding a significant effect of BCAA on
    HE was found
  • BCAA had no significant effect on survival when
    given parenterally to acute HE or enterally to
    chronic HE
  • Discrepancy between each applied model (fixed vs
    random)
  • Trend towards beneficial effect of BCAA using
    best-case analysis with fixed model only p0.03
    vs p0.13 with random
  • No significant effect of BCAA with worst-case
    analysis

65
Conclusions
  • No convincing evidence that BCAA had a
    significant beneficial effect on improvement of
    HE or survival in patients with HE
  • Small trials with short f/u and most of poor
    quality
  • Primary analysis showed a significant benefit of
    BCAA on HE, but significant statistical
    heterogeneity was present and result not robust
    to sensitivity analysis
  • Low methodological quality source of
    heterogeneity (bias)
  • Benefits of BCAA on HE only observed when lower
    quality studies included
  • Effect size and small study bias
  • No significant association between dose or
    duration and the effect of BCAA

66
Conclusions
  • In general, BCAAs were more effective when given
    enterally to subjects with chronic
    encephalopathy, then when given IV to patients
    with acute encephalopathy
  • Most likely through improved nutrition

67
TABLE 1 Randomized controlled trials of BCAA
treatment in cirrhosis1
1 bw, body weight co, crossover study pg,
parallel group design. 2 Dietary BCAA not
included. Data are in g/d except as noted. 3
Positive, BCAA significantly different negative,
BCAA not significantly different.
68
Limitations
  • Significant heterogeneity among studies (ie.,
    patient populations, settings, routine care)
    making a meta-analysis decipherable
  • Division of HE into categories is arbitrary and
    precipitating factors not always identified
  • The definition of improvement different among
    studies
  • Scales and items used for defining and assessing
    HE are arbitrary and not tested for reliability
    or validity

69
Implications For Future Research
  • The absence of evidence for an effect of BCAA
    does not mean there is evidence of lack of effect
  • Future randomized trials warranted
  • Trials could randomize according various types of
    HE to BCAA versus placebo
  • All trials should use parallel group design
  • Spontaneously fluctuating nature of HE
  • Need for assessing outcomes (improvement,
    recovery, mortality, and adverse events) after
    end of treatment
  • There is substantial need for clear diagnostic
    criteria of HE, as well as reassessment and
    validation of scales and items used for measuring
    its course

70
Implications For Future Research
  • New studies are awaited to identify patients at
    higher risk where BCAA is probably the only way
    to prevent catabolic losses and improve prognosis
  • Dose-finding studies are needed to detect optimum
    dosage, safe limits of administration, and
    whether higher doses will show more benefit
  • Studies needed to define whether all 3 BCAAs
    need to be supplied
  • Effects of leucine on protein turnover and HGF
    secretion
  • Leucine alone might achieve similar beneficial
    results at lower total doses

71
BCAA Enteral Formulations
  • NutriHep Enteral Nutrition (Nestle)
  • 1.5 kcal/mL
  • Fat (12) MCT (66)
  • Protein 50 BCAA, low MET
  • CHO 77
  • RDI 100
  • Gluten-free, lactose-free
  • Hepatic-Aid II (Hormel Health Labs)
  • 1.2 kcal/mL
  • Fat (28) No MCT
  • Protein 46 BCAA, low AAA
  • CHO 58
  • Vitamin and Electrolyte-free

72
The Child-Turcotte-Pugh Classification
73
Goals of MNT for HE
  • Treatment of PCM associated with Underlying Liver
    Disease
  • Suppression of endogenous protein breakdown to
    reduce stress placed on de-compensated liver
  • Achieve positive nitrogen balance without
    exacerbating neurological symptoms
  • PCM associated with morbidity and mortality in
    cirrhosis (65-90 with PCM)
  • Severity of pcm positively correlated with
    mortality

74
Nutritional ImplicationsPCM associated Liver
Dz
  • Nutrient malabsorption/ maldigestion
  • Cholestatic non-cholestatic liver disease
  • Excessive protein losses
  • Pancreatic insufficiency
  • Abnormal Metabolism
  • Hypermetabolism
  • Hyperglucogonemia
  • Increased protein metabolism
  • Increased lipid oxidation
  • Osteopenia
  • Malnutrition reported in 65-90 cirrhotic pts
  • Poor Dietary Intake
  • Anorexia
  • Dietary Restrictions
  • Ascites
  • Gastroparesis
  • Zinc Deficiency
  • Increased proinflammatory cytokines

75
MNT in Advanced Liver Disease
  • Poor Dietary Intake
  • Due to poor appetite, early satiety with ascites
  • Small frequent meals
  • Aggressive oral supplementation
  • Zinc supplementation
  • Nutrient Malabsorption
  • Due to bile, failure to convert to active
    forms
  • ADEK supplementation
  • Calcium D supplementation
  • Folic Acid Supplementation

76
MNT in Advanced Liver Disease
  • Abnormal Fuel Metabolism
  • Increased perioxidation, gluconeogenesis
  • Bedtime meal to decrease
  • Protein Deficiency
  • protein catabolism, repeat paracentesis
  • High protein snacks/supplements
  • 1.2-1.5 gms/day

77
MNT in Advanced Liver Disease
  • Standard Guidelines
  • MVI with minerals
  • 2gm Na restriction in presence of ascites
  • Do not restrict fluid unless serum Na lt120mmol
  • Low threshold for NGT in pts awaiting transplant
  • TPN should be considered only if contraindication
    for enteral feeding

78
How Much Protein That is the Question
  • Grade III to IV hepatic encephalopathy
  • Usually no oral nutrition
  • Upon improvement, individual protein tolerance
    can be titrated by gradually increasing oral
    protein intake every three to five days from a
    baseline of 40 g/day
  • Oral protein not to exceed 70 g/day if pt has hx
    if hepatic encephalopathy
  • Below 70 g/day rarely necessary, minimum intake
    should not be lower than 40 g/day to avoid
    negative nitrogen balance

79
MNT Specifically in HE
  • Non-protein energy 35-45 kcal/kg/day
  • Up to 1.6g/kg/day protein as tolerated
  • Low-grade HE (minimal, I, II) should not be
    contraindication to adequate protein supply
  • 40g temporary restriction if considered protein
    intolerant, but gradual increase q3-5 days
  • 30-40g Vegetable protein/day for these pts
  • In patients intolerant of a daily intake of 1 g
    protein/kg, oral BCAA up to 0.25 g/kg may be
    beneficial to create best possible nitrogen
    balance
  • BCAAs do not exacerbate encephalopathy

80
MNT Specifically in HE
  • HE coma (grade III-IV)
  • Usually no oral nutrition
  • Upon improvement, individual protein tolerance
    can be titrated by gradually increasing oral
    protein intake every three to five days from a
    baseline of 40 g/day
  • Enteral and parenteral regimens providing 25-30
    kcal/kg/day non-protein energy
  • 1.0g/kg/day protein, depending on degree of
    muscle wasting
  • BCAA-enriched solutions may benefit protein
    intolerant (lt1g/kg)

81
Conclusions in HE Management
  • Intervention directed against the precipitating
    cause(s) will lead to improvement or
    disappearance of acute hepatic encephalopathy
  • Our understanding of pathogenesis is improving,
    but much work remains
  • Link between liver and brain still only partially
    understood
  • No evidence supporting standard use of BCAA
    formulations, but may benefit small subgroup
  • Cost analysis not conducted in trials
  • Cost outweigh benefits for standard protocol

82
Thank You!
  • Special Thanks to Nicole Varady
  • Comments?
  • Questions?

83
References
  • Müller, M. J., Selberg, O. Böker, K. (1994) Are
    patients with liver cirrhosis hypermetabolic?.
    Clin. Nutr. 13131-144.
  • The ESPEN Consensus GroupPlauth, M., Merli, M.,
    Kondrup, J., Weimann, A., Ferenci, P. Muller,
    M. J. (1997) ESPEN guidelines for nutrition in
    liver disease and transplantation. Clin. Nutr.
    1643-55.
  • Falck-Ytter, Y., Younossi, Z. M., Marchesini, G.
    McCullough, A. J. (2001) Clinical features and
    natural history of nonalcoholic steatosis
    syndromes. Semin. Liver Dis. 2117-26.
  • Italian Multicentre Cooperative Project on
    nutrition in liver cirrhosis (1994) Nutritional
    status in cirrhosis. J. Hepatol. 21317-325.
  • Marchesini, G., Bianchi, G., Amodio, P., Salerno,
    F., Merli, M., Panella, C., Loguercio, C.,
    Apolone, G., Niero, M. Abbiati, R. (2001)
    Factors associated with poor health-related
    quality of life of patients with cirrhosis.
    Gastroenterology 120170-178.
  • Selberg, O., Bottcher, J., Tusch, G., Pichlmayr,
    R., Henkel, E. Muller, M. J. (1997)
    Identification of high- and low-risk patients
    before liver transplantation a prospective
    cohort study of nutritional and metabolic
    parameters in 150 patients. Hepatology
    25652-657.
  • James, J. H., Ziparo, V., Jeppsson, B. Fischer,
    J. E. (1979) Hyperammonaemia, plasma amino acid
    imbalance, and blood-brain amino acid transport
    a unified theory of portal-systemic
    encephalopathy. Lancet 2772-775.
  • Naylor, C. D., ORourke, K., Detsky, A. S.
    Baker, J. P. (1989) Parenteral nutrition with
    branched-chain amino acids in hepatic
    encephalopathy. A meta-analysis. Gastroenterology
    971033-1042.
  • Fabbri, A., Magrini, N., Bianchi, G., Zoli, M.
    Marchesini, G. (1996) Overview of randomized
    clinical trials of oral branched-chain amino acid
    treatment in chronic hepatic encephalopathy. J.
    Parenter. Enteral Nutr. 20159-164.
  • Als-Nielsen, B., Koretz, R. L., Kjaergard, L. L.
    Gluud, C. (2004) Branched-chain amino acids for
    hepatic encephalopathy (Cochrane review). The
    Cochrane Library, Issue 2 2004 John Wiley and
    Sons Chichester, UK .
  • Ishiki, Y., Ohnishi, H., Muto, Y., Matsumoto, K.
    Nakamura, T. (1992) Direct evidence that
    hepatocyte growth factor is a hepatotrophic
    factor for liver regeneration and has a potent
    antihepatitis effect in vivo. Hepatology
    161227-1235.
  • Tomiya, T., Inoue, Y., Yanase, M., Arai, M.,
    Ikeda, H., Tejima, K., Nagashima, K., Nishikawa,
    T. Fujiwara, K. (2002) Leucine stimulates the
    secretion of hepatocyte growth factor by hepatic
    stellate cells. Biochem. Biophys. Res. Commun.
    2971108-1111.
  • Fenton, J. C., Knight, E. J. Humpherson, P. L.
    (1966) Milk-and-cheese diet in portal-systemic
    encephalopathy. Lancet 1164-166.
  • Bianchi, G. P., Marchesini, G., Fabbri, A.,
    Rondelli, A., Bugianesi, E., Zoli, M. Pisi, E.
    (1993) Vegetable versus animal protein diet in
    cirrhotic patients with chronic encephalopathy. A
    randomized cross-over comparison. J. Intern. Med.
    233385-392.
  • Rossi-Fanelli, F., Riggio, O., Cangiano, C.,
    Cascino, A., De Conciliis, D., Merli, M.,
    Stortoni, M., Giunchi, G. Capocaccia, L. (1982)
    Branched-chain amino acids vs. lactulose in the
    treatment of hepatic coma. A controlled study.
    Dig. Dis. Sci. 27929-935.

84
References
  • Wahren, J., Denis, J., Desurmont, P., Eriksson,
    L. S., Escoffier, J. M., Gauthier, A. P.,
    Hagenfeldt, L., Michel, H. Opolon, P., et al
    (1983) Is intravenous administration of branched
    chain amino acids effective in the treatment of
    hepatic encephalopathy?. A multicenter study.
    Hepatology 3475-480.
  • Michel, H., Bories, P., Aubin, J. P.,
    Pomier-Layrargues, G., Bauret, P.
    Bellet-Herman, H. (1985) Treatment of acute
    hepatic encephalopathy in cirrhotics with a
    branched-chain amino acids enriched versus a
    conventional amino acids mixture. A controlled
    study of 70 patients. Liver 5282-289.
  • Cerra, F. B., Chung, N. K., Fischer, J. E.,
    Kaplowitz, N., Schiff, E. R., Dienstag, J. L.,
    Bower, R. H., Mabry, C. D., Leevy, C. M.
    Kiernan, T. (1985) Disease-specific amino acid
    infusion (F080) in hepatic encephalopathy a
    prospective, randomized, double-blind controlled
    trial. J. Parenter. Enteral Nutr. 9288-295.
  • Fiaccadori, F., Ghinelli, F., Pedretti, G.,
    Pelosi, G., Sacchini, D., Zeneroli, M. L.,
    Rocchi, E., Gibertini, P. Ventura, E. (1985)
    Branched-chain enriched amino acid solutions in
    the treatment of hepatic encephalopathy a
    controlled trial. Ital. J. Gastroenterol.
    175-10.
  • Strauss, E., dos Santos, W. R., da Silva, E. C.,
    Lacet, C. M., Capacci, M.L.L. Bernardini, A. P.
    (1986) Treatment of hepatic encephalopathy a
    randomized clinical trial comparing branched
    chain enriched amino acid solution to oral
    neomycin. Nutr. Supp. Services 618-21.
  • Vilstrup, H., Gluud, C., Hardt, F., Kristensen,
    M., Køler, O., Melgaard, B., Dejgaard, A.,
    Hansen, B. E. Krintel, J. J., et al (1990)
    Branched chain enriched amino acids versus
    glucose treatment of hepatic encephalopathy. A
    double-blind study of 65 patients with cirrhosis.
    J. Hepatol. 10291-296.
  • Eriksson, L. S., Persson, A. Wahren, J. (1982)
    Branched-chain amino acids in the treatment of
    chronic hepatic encephalopathy. Gut 23801-806.
  • Sieg, A., Walker, S., Czygan, P., Gärtner, U.,
    Lanzinger-Rossnagel, G., A., S. Kommerell, B.
    (1983) Branched-chain amino acid-enriched
    elemental diet in patients with cirrhosis of the
    liver. Z. Gastroenterol. 21644-650.
  • Simko, V. (1983) Long-term tolerance of a special
    amino acid oral formula in patients with advanced
    liver disease. Nutr. Rep. Int. 27765-773.
  • Horst, D., Grace, N. D., Conn, H. O., Schiff, E.,
    Schencker, S., Viteri, A., Law, D. Atterbury,
    C. E. (1984) Comparison of dietary protein with
    an oral, branched chain-enriched amino acid
    supplement in chronic portal-systemic
    encephalopathy. Hepatology 4279-287.
  • Christie, M. L., Sack, D. M., Pomposelli, J.
    Horst, H. (1985) Enriched branched-chain amino
    acid formula vs. a casein-based supplement in the
    treatment of cirrhosis. J. Parenter. Enteral
    Nutr. 9671-678.
  • Egberts, E. H., Schomerus, H., Hamster, W.
    Jürgens, P. (1985) Branched chain amino acids in
    the treatment of latent portosystemic
    encephalopathy. A double-blind placebo-controlled
    cross-over study. Gastroenterology 88887-895.
  • Fiaccadori, F., Elia, G. F., Lehndorff, H.,
    Merli, M., Pedretti, G., Riggio, O. Capocaccia,
    L. (1988) The effect of dietary supplementation
    with branched-chain amino acids vs. casein in
    patients with chronic recurrent portal systemic
    encephalopathy a controlled trial. Soeters, P.
    B. Wilson, J.H.P. Meijer, A. J. Holm, E. eds.
    Advances in Ammonia Metabolism and Hepatic
    Encephalopathy 1988489-497 Excerpta Medica
    Amsterdam, The Netherlands. .
  • Swart, G. R., van den Berg, W. O., van Vuure, J.
    K., Rietveld, D., Wattimena, D. L. Frenkel, M.
    (1989) Minimum protein requirements in liver
    cirrhosis determined by nitrogen balance
    measurements at three levels of protein intake.
    Clin. Nutr. 8329-336.
  •  

85
References
  • Marchesini, G., Dioguardi, F. S., Bianchi, G. P.,
    Zoli, M., Bellati, G., Roffi, L., Martines, D.
    Abbiati, R. the Italian Multicenter Study Group
    (1990) Long-term oral branched-chain amino acid
    treatment in chronic hepatic encephalopathy. A
    randomized double-blind casein-controlled trial.
    J. Hepatol. 1192-101.
  • Marchesini, G., Bianchi, G., Merli, M., Amodio,
    P., Panella, C., Loguercio, C., Rossi Fanelli, F.
    Abbiati, R. (2003) Nutritional supplementation
    with branched-chain amino acids in advanced
    cirrhosis a double-blind, randomized trial.
    Gastroenterology 1241792-1801.
  • Lieber, C. S. (2000) Alcoholic liver disease new
    insights in pathogenesis lead to new treatments.
    J. Hepatol. 32113-128.
  • Marsano, L. McClain, C. J. (1991) Nutrition and
    alcoholic liver disease. J. Parenter. Enteral
    Nutr. 15337-344.
  • Merli, M., Nicolini, G., Angeloni, S. Riggio,
    O. (2002) Malnutrition is a risk factor in
    cirrhotic patients undergoing surgery. Nutrition
    18978-986.
  • Fan, S. T., Lo, C. M., Lai, E. C., Chu, K. M.,
    Liu, C. L. Wong, J. (1994) Perioperative
    nutritional support in patients undergoing
    hepatectomy for hepatocellular carcinoma. N.
    Engl. J. Med. 3311547-1552.
  • The San-in Group of Liver Surgery (1997)
    Long-term oral administration of branched chain
    amino acids after curative resection of
    hepatocellular carcinoma a prospective
    randomized trial. Br. J. Surg. 841525-1531.
  • Poon, R. T., Yu, W. C., Fan, S. T. Wong, J.
    (2004) Long-term oral branched chain amino acids
    in patients undergoing chemoembolization for
    hepatocellular carcinoma a randomized trial.
    Aliment. Pharmacol. Ther. 19779-788.
  • Reilly, J., Mehta, R., Teperman, L., Cemaj, S.,
    Tzakis, A., Yanaga, K., Ritter, P., Rezak, A.
    Makowka, L. (1990) Nutritional support after
    liver transplantation a randomized prospective
    study. J. Parenter. Enter Nutr. 14386-391.
  • Bilbao, I., Armadans, L., Lazaro, J. L., Hidalgo,
    E., Castells, L. Margarit, C. (2003) Predictive
    factors for early mortality following liver
    transplantation. Clin. Transplant. 17401-411.
  • Tietge, U. J., Bahr, M. J., Manns, M. P. Boker,
    K. H. (2003) Hepatic amino-acid metabolism in
    liver cirrhosis and in the long-term course after
    liver transplantation. Transpl. Int. 161-8.
  • Charlton, M. (2003) Branched-chain amino
    acid-enriched supplements as therapy for liver
    disease Rasputin lives. Gastroenterology
    1241980-1982.
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