GIT, Hepatobiliary, Pancreatic

Question 1

Zones in the liver & implications?

Answer 1

Zone 1: periportal - most prone to toxic injury. Site mainly affected by SECONDARY causes of Cu accumulation.
Zone 2:
Zone 3: centrilobular - most prone to hypoxic injury. Site mainly affected with PRIMARY defects in Cu accumulation.

Question 2

Breeds predisposed to copper storage hepatopathy?

Answer 2

Pure + mixed breeds.
Bedlington terriers, Labs, WHWT, Dobermans, Skye terrier, Dalmatians.

Question 3

Copper storage hepatopathy in Bedlington terriers - gene mutation, clinical characteristics?

Answer 3

Autosomal recessive disorder.
Deletion of exon 2 of copper metabolism domain containing 1 (COMMD1) gene –> complete absence of protein that normally regulates copper metabolism & homeostasis –> affects biliary copper excretion pathway –> copper accumulation in hepatocellular lysosomes.
Acute form - 2-6yo, hepatomegaly, jaundice, hemolytic anemia. Elevated ALT.
Chronic form - middle-aged and older dogs. Less severe CSx, progressive liver damage.
Dx - liver bx. BUT liver [Cu] does not always correlate with the extent of liver damage & dz progression, also may not ID substantial Cu accumulation in hepatocytes in early dz.

Question 4

Copper metabolism pathway and transporter genes involved?

Answer 4

Copper homeostasis relies on regulation of uptake of copper in
the small intestine, cellular metabolism executed by a variety of copper transporters and chaperones, as well as excretion of excessive copper via the biliary tract.

The P-type copper-transporting ATPases, ATP7A and ATP7B are crucial for the regulation of copper homeostasis.
- ATP7A mainly resides at the basal membrane of enterocytes and facilitates copper transport into the portal circulation.
- ATP7B is located at the Golgi complex in hepatocytes and moves to the endo-lysosomal cellular compartments upon copper overload. ATP7B has a dual function. In terms of its biosynthetic role, ATP7B facilitates incorporation of copper into apo-ceruloplasmin within the trans-Golgi network to form ceruloplasmin. Furthermore, ATP7B facilitates excretion of copper into the bile via the apical membrane of hepatocytes.

Question 5

Cu associated hepatitis in Labs - causative gene mutation?

Answer 5

Mutations in ATP7A & ATP7B genes leading to amino acid substitutions.

Question 6

WSAVA classification of feline inflammatory liver diseases?

Answer 6

3 histopath groups:
1) Neutrophilic (acute & chronic)
2) Lymphocytic
3) Chronic cholangitis 2’ to liver flukes (Platynosomum spp. and Amphimerus pseudofelineus)

Question 7

Liver fluke cholangitis in cats - pathogenesis?

Answer 7

Endemic - ‘lizard poisoning’ - eating
infected lizards found in the tropics and subtropics. Fluke resides in the GB & biliary ducts of infected cats, creating inflammation within bile ducts & portal areas.
High burden –> chronic mucoid D+ & icterus. Non-specific signs when chronic (adult flukes persist).

Question 8

Hepatocutaneous syndrome - signalment, skin lesion appearance & locations?

Answer 8

Signalment: small-med sized dogs, males > females, median onset 10yo. Breeds reported - Shetland, Cockers, WHWT.

Skin: crusting, ulcerative, painful dermatosis
that affects the mucocutaneous junctions, pressure
points, and footpads with classic histologic features of superficial necrolytic dermatitis

Question 9

What do the CCECAI and CIBDAI systems stand for (differences) and what is their clinical utility?

Answer 9

Both systems used for scoring dogs with IBD. CIBDAI has also been utilised to assess dogs with acute pancreatitis.

CIBDAI = canine IBD activity index.
= 6 components, attitude/activity, appetite, vomiting, stool consistency, stool frequency, weight loss (see table)

CCECAI = canine chronic enteropathy clinical activity index.
= CIBDAI components + serum [albumin], peripheral oedema & ascites, severity of pruritus.
allows better assessment of therapeutic success

Question 10

Describe the technique of contrast-enhanced ultrasound & its indications.

Answer 10

Salavati JVIM 2020
CEUS uses gas-filled microbubbles (usually sulfur hexafluoride) as a tracer to assess tissue perfusion. The microbubbles remain entirely within the intravascular space & have rheology (flow & deformation) similar to RBCS. Excess sulfur hexafluoride is exhaled, and the phospholipid microbubble shell enters the endogenous phospholipid metabolic pathway. The microbubbles have an elimination half-life of ~6mins; >80% of the administered gas is exhaled via the lungs after 11 mins.

Indications:
Humans - assess mucosal healing with IBD
Dogs - evaluate perfusion abnormalities in several organs (focal splenic lesions, adrenal tumors, prostatic disease); assessment of GIT in healthy dogs & cats, assess duodenal perfusion in dogs with CIE & intestinal LSA.

Question 11

a) DGGR lipase vs traditional lipase assay components?

b) Agreement of DGGR lipase with current gold standard tests for diagnosis of pancreatitis?

Answer 11

a) DGGR lipase assay = 1,2-O-dilauryl-rac-glycero glutaric acid-(60-methylresorufin) ester (DGGR) substrate. Traditional lipase = 1,2-diglyceride (1,2 DiG) substrate.

b) High level of agreement between DGGR & spec CPL, similar sensitivity. DGGR is cheaper with more rapid turnaround time, used as screening biomarker in routine biochemistry panels.

Question 12

Normal hepatic [copper] in dogs?

Answer 12

150-400 μg/g dry weight (parts per million/ppm).

Question 13

Cut-off hepatic Cu level for differentiating primary vs secondary copper hepatopathy?

Answer 13

<800ppm likely secondary
>800ppm likely primary

Question 14

What is the current best indicator of cobalamin (Cbl) status in cats & dogs?
What is the role of this indicator in B12 metabolism?

Answer 14

Measurement of methylmalonic acid (MMA) concentrations - indicator of Cbl cellular stores.

Adenosyl-Cbl = cofactor for a) conversion of methylmalonyl-CoA to succinyl-CoA via methylmalonyl-CoA mutase, and b) re-methylation of homocysteine via methionine synthase.

B12 deficiency –> decreased methylmalonyl-CoA mutase activity –> increased serum [MMA].
NB: cats don’t have increased [homocysteine].

Question 15

Roles of bile acids?

Answer 15

• Aid in digestion & absorption of lipids in the GIT
• Signalling molecules
• Primary BA converted to secondary BA by bacteria with 7α-dehydroxylation capabilities.
• Secondary BAs inhibit growth & germination of C. difficile (in people, possibly in dogs).

Question 16

1) Which bacteria is involved in bile acid metabolism?
2) Significance in dogs/cats with CE?
3) Diagnostic test available?

Answer 16

1) Clostridium hiranonis
Main BA converting bacteria spp in dogs - convert primary BAs to secondary BAs by 7a-dehydroxylation
2) Depleted in CE (also by abx use) –> decreased proportion of secondary BA in colon in these dogs. Can be partially restored with FMT.
3) Included as 1 of 7 bacteria spp. quantified with the faecal dysbiosis index (DI).

Question 17

List primary & secondary bile acids, and their roles.

Answer 17

Primary BA:
- Cholic acid, chenodeoxycholic acid
- In the duodenum: solubilise dietary lipids to aid digestion post-prandium

Secondary BA:
- Deoxycholic acid, lithocholic acid
- Bind to transmembrane G protein-coupled bile acid receptor GPBAR-1 (AKA TGR5 as signaling molecules)
- Anti-inflammatory properties.
- Lower glucose concentrations by binding to the farnesoid X receptor.

Question 18

Differences in bile acid conjugation between cats & dogs?

Answer 18

• Cats: BA exclusively conjugated with taurine (essential AA) - so prone to rapidly developing taurine deficiency with hepatic disease
• Dogs: taurine or glycine

Question 19

Risk factors for PPDH in dogs & cats?

Answer 19

Dogs - Weimaraners
Cats - DMH, DLH (Himalayans, Persians)

Question 20

Ductal plate malformations:
1. Define
2. Phenotypes
3. Complications/consequences

Answer 20

1. DPMs = embryonic abnormalities secondary to dysfunction of the primary cilia that result in defective tubulogenesis & affect the formation of bile ducts. (Primary cilia are present in the liver on only
   cholangiocytes, not hepatocytes).
2. Caroli DPM (malformative medium-to-large bile ducts with irregularly distended or variably sacculated silhouettes, evaginating diverticular buds, and occasional scattered circumferential satellite bile duct profiles, similar to the embryologic ductal plate) or proliferative-like DPM. 1st r/o mechanical cholestasis before diagnosis.
   Expansive cystadenoma DPM - cats > dogs
3. Pre-sinusoidal hypertension develops due to non-compliant portal fibrosis. Congenital hepatic fibrosis –> variable clinical progression but can lead to acquired PSS & ascites.

Question 21

Which immunohistochemical stains are used to diagnosed copper storage hepatopathy?

Answer 21

Rhodanine stain - highlights copper granules as bright orange-red cytosolic inclusions. Limitation - stain fades over time esp with light exposure (overcome by digitally staining fresh slides).

Question 22

Copper storage hepatopathy
- Breeds
- Causal gene mutation?
- Pathogenesis

Answer 22

• Bedlington Terriers, Dobers, Labs
• COMMD1 - homozygous deletion of exon 2 (Bedlington)
• SNP (all 3 above)

Complete absence/dysfunction of ATP7β (Cu transporter protein responsible for Cu transport into plasma protein ceruloplasmin & Cu bile elimination)

Question 23

Describe how copper accumulation causes liver injury.

Answer 23

Cu exists in an oxidized (cupric [Cu2+]) or reduced (cuprous [Cu1+]) state - so functions as electron acceptor or donor. Allows Cu to participate in redox cycling reactions that promote generation of ROS.
Haber-Weiss/Fenton reaction: generates superoxide (O2−), hydroxyl (OH) radicals & other ROS from H2O2. Effects of ROS: break DNA strands, ER stress & oxidative injury to cell & mitochondrial membranes, impair protein synthesis + promote cell death pathways. Oxidative injury –> consumptive depletion of hepatocytes & mitochondiral antioxidants (glutathione & a-tocopherol) –> perpetuates oxidative injury.
Decreased hepatic & plasma gluthathione & vit E [ ]
Can also exacerbate oxidative injury caused by concurrent extra-hepatic illness (due to glutathione depletion)

Question 24

Describe histopath findings encountered with copper storage hepatopathy.

Answer 24

1. Accumulation of refractile eosinophilic cytosolic granules in centrilobular (rather than periportal) hepatocytes. Often colocalize with lipofuscin (tan-colored product derived from oxidized membrane lipids).
2. Copper pigment granulomas - cellular response to dead/dying hepatocytes; populated by macrophages (containing phagocytized hemosiderin, copper, and lipofuscin-laden debris) > fewer lymphocytes, occ Np. Can extend to all zones with progressive disease
3. Lymphohistiocytic infiltrates
4. Hepatocyte microvesicular lipid vacuolation - result of mitochondrial & ER injury, seen in severe disease
5. Mp may sequester iron (phagocytosis of heme-rich cell debris)
6. Progressive disease - parenchymal remodelling & fibrosis, see regenerative nodules.
7. Advanced disease - loss of acinar structures & parenchymal distinction. Grossly small pale firm liver with many nodules.
8. With cirrhosis, Cu accumulates in areas of inflammatory infiltrates or at the margins of regenerative nodules

Question 25

What are indications for initiating copper chelation therapy in dogs?

Answer 25

> 1500 mcg/g dry weight regardless of distribution
750 mcg/g dry weight if there is centrilobular accumulation esp in predisposed breeds

Center JAVMA 2021 update: >/=600mcg/g DW if histologic lesions seen with hepatocyte Cu accumulation or if fluctuating ALT activities are seen with no alternative identifiable cause. (as low as 600mcg/g has been associated with copper storage hepatopathy).

Question 26

What are 2 rare complications of severe copper storage hepatopathy in dogs?

Answer 26

1. Acute, severe panlobular hepatic necrosis - associated with massive Cu release from damaged hepatocytes –> may cause markedly increased circulating [Cu] & haemolysis. Grossly liver appears normal/plump or has soft pale-yellow necrotic foci.
2. Acquired Fanconi syndrome (euglycemic glucosuria > acute proximal tubular injury). Can visualise Cu accumulation in PT epithelium of renal biopsies with Rhodanine staining. Clinical recovery possible with intensive supportive care.

Question 27

What are 2 rare complications of severe copper storage hepatopathy in dogs?

Answer 27

1. Acute, severe panlobular hepatic necrosis - associated with massive Cu release from damaged hepatocytes –> may cause markedly increased circulating [Cu] & haemolysis. Grossly liver appears normal/plump or has soft pale-yellow necrotic foci.
2. Acquired Fanconi syndrome (euglycemic glucosuria > acute proximal tubular injury). Can visualise Cu accumulation in PT epithelium of renal biopsies with Rhodanine staining. Clinical recovery possible with intensive supportive care.

Question 28

Liver copper accumulation in cats - causes & differences with dogs?

Answer 28

Cats with slowly progressive cholangitis –> cholestasis –> periportal Cu accumulation.
Vs dogs - pathological hepatic Cu accumulation is centrilobular, cholestasis is an uncommon cause for significant Cu accumulation (even with EHBDO)

Question 29

What are the key GI bacterial phyla in dogs and cats?

Answer 29

Firmicutes, Bacteroidetes, Proteobacteria, Fusobacteria, Actinobacteria

Question 30

What RBC abnormalities are more common in dogs with GI lymphoma vs chronic enteropathy?

Answer 30

Parachini-Winter JAVMA 2019
Anaemia
3+ RBC anomalies, (Sn 71%, Sp 70%)
Particularly presence of eccentrocytes (29% LSA vs 4% CIE)

Eccentrocytes reflect oxidative injury.

Question 31

Differences in oesophagus musculature between dogs & cats? Implications for treatments?

Answer 31

Dogs - striated muscle throughout oesophagus
Cats - upper 80% striated, distal 20% smooth muscle
Smooth muscle agents (metoclopramide & cisapride) don’t work to increase oesophageal motility in dogs, but may work to increase distal oesophageal motility in cats.

Question 32

What are the 2 types of cricopharyngeal dysphagia?

Answer 32

1. Achalasia = a primary esophageal motility disorder; results from a selective loss of inhibitory myenteric neurons leading to failure of the LES to relax in response to a pharyngeal swallow and impaired esophageal peristalsis.
2. Assynchrony = lack of coordination between UES relaxation & pharyngeal contraction.

Clinical signs are indistinguishable.

Question 33

Which drugs may be associated with GB mucocoele formation?

Answer 33

Thyroxine, trilostane, imidocloprid (esp in Shetland sheepdogs)

Question 34

Nutritional deficiency in …… is of potential concern in dogs with GBM, due to ……

Answer 34

Lipid-soluble substances
EHBDO

Question 35

DDx for hyperammonemia in dogs/cats?
1 blood test that may help differentiate?

Answer 35

Congenital vs acquired PSS, inborn errors of metabolism (IEM; urea cycle enzyme deficiency)
BAST - normal with IEM
Also IEM - young animals. Can measure urine metabolites. Reported in Irish Wolfhounds (hypercitrullinemia). Pekingese, Yorkie; American shorthair, Maine coon.

Question 36

What are the 3 main zymogens in the exocrine pancreas? What 2 mechanisms prevent early activation of pancreatic enzymes & autodigestion?

Answer 36

Zymogens - trypsinogen (main one), chymotrypsinogen, procarboxypeptidase
Mechanisms:
- Presence of chyme required –> enterocytes (brush border enzymes) release enteropeptidase –> activates some trypsinogen to trypsin –> newly formed trypsin assists in activating all three zymogens
- Intracellular pancreatic secretory trypsin inhibitor (PTSI) released to inhibit early activation of pancreatic enzymes

Question 37

What are the key players regulate pancreatic enzyme secretion?

Answer 37

1. Presence of fat and protein in the SI lumen (70% secretions) > thought of food (cephalic phase) (20%) > stomach filling (gastric phase 5-10%)
2. Secretin (from S cells in duodenum & jejunum) = most impt hormone that stimulates pancreatic secretion containing HCO3- (+ H2O) in response to HCl in chyme entering SI from stomach.
3. Ach (vagal n.) & cholecystokinin (CCK) –> stimulate release of digestive enzymes (+release of bile into SI).
4. Local enteric NS.

Question 38

In which breed with chronic pancreatitis may immunosuppressive therapy be beneficial?

Answer 38

English Cocker Spaniels
Distinct form of CP vs other breeds, similar to autoimmune CP in humans (histo - duct destruction + anti-CD31 lymphocytic infiltrates around venules and ducts)
Other breeds: usually mixed T-cell infiltration & duct hyperplasia on histo.

Question 39

Which bacteria spp can compete with the host for to utilize the B12-IF-receptor complexes in the development of SI dysbiosis?

Answer 39

Bacteroides spp. (other bacteria can only complete for free B12)

Question 40

High folate - causes & mechanisms?

Answer 40

SI dysbiosis (Bacteroides spp produce folate)
B12 deficiency (folate share common methionine synthesis pathway. B12 def –> traps & accummulates folate –> can decr after B12 supp)

Question 41

Immunoproliferative LP enteritis has been documented in which breed? What are the characteristic clin path & histological features of this disease?

Answer 41

Basenjis.
Marked hypoalb + HYPERglob (don’t have alpha heavy chain dz like in humans). Predisposition to LSA.
Histo of intestinal lesions - increased CD4+ & CD8+ T cells.

Question 42

A specific enteropathy in Irish Setters involves sensitivity to what ingredient? What is another breed with similar sensitivity?

Answer 42

Gluten.
SCWTs (PLE).

Question 43

What molecular weight of proteins are associated with immunological responses causing GI disease in dogs & cats?

Answer 43

20+kDa
Most common types: beef, dairy, fish (for cats)

Question 44

List 5 dog breeds prediposed to EPI? Differences in most common aetiology?

Answer 44

Progressive acinar atrophy
-** GSD, Rough coated collies **(autosomal recessive)
- Chow Chow (congenital hypoplasia also reported)
- English Setters (reported in family)

Chronic pancreatitis
- CKCS

Question 45

TLI:
- Cut-off to diagnose EPI (cats vs dogs)?
- Causes for increased TLI?

Answer 45

Dogs: <2.5ug/L (with concurrent CSx) highly diagnostic, <1.9ug/L 100% Sp/Sn.
Cats: <8.0ug/L diagnostic
Increased TLI - pancreatitis, renal disease (decr excretion), pancreatic duct obstruction, post-prandium (12-18hr fast)
Interference - hemolysis

Question 46

What 2 other tests can be considered to diagnose EPI in the event of equivocal TLI results? Cut-offs for EPI vs normal?

Answer 46

1. Faecal pancreatic elastase 1 (FPE1)
   - Zymogen produced exclusively within pancreatic acinar cells. Survives intestinal transit unchanged, also unaffected by intestinal inflammation.
   - <10ug/g faeces diagnostic for EPI, >40ug/g = normal exocrine pancreatic function
2. TLI stimulation test
   - Measure cTLI before & 20mins after stimulation with secretin/CCK IV
   - Lack of stimulation confirms EPI (subclinical EPI - can have low fasting but normal post stim results)
   - In people gold standard: analyse pancreatic secretions after CCK & secretin stimulation, some studies in dogs (but impractical)
3. Or…just recheck TLI 1 month after

Question 47

Which pancreatic enzyme formulation is recommended (vs not) for EPI tx?

Complications/possible causes for no clinical response to supp?

Answer 47

• Powdered forms recc (commerical vet products available)
• Enteric-coated pancreatic enzyme tablets NOT recommended (need pancreatic HCO3- to break down coating, deficient in EPI patients, also don’t recc supp)
• Raw pancreas not recc (BSE, pseudorabies!)

Causes:
- Too low dose
- Inappropriate formulation (enteric coated tabs)
- HypoB12 (not supp)
- Vit K def > coagulopathy (reported)
- Co-morbidities unaddress (IBD, ARE, pancreatitis)
- Dietary (some dogs may need lower fat)

Question 48

Dietary recommendation for EPI?

Answer 48

Highly digestible (low fibre), moderate fat (or adjusted based on patient)
Low fat not proven to improve CSx.

Question 49

Normal CBD diameter in dogs vs cats?

Answer 49

Dogs: not normally seen on US, <3mm
Cats </= 4mm
(shouldn’t see intrahepatic bile ducts)

Question 50

Liver of dog - most likely ddx? Common concurrent clinical manifestation?

Answer 50

Hepatocutaneous syndrome. Honeycomb appearance (hypoechoci nodules with hyperechoic liver parenchyma)
Superficial necrolytic dermatitis - pedal skin lesions

Question 51

What gene mutation is associated with predisposition to pancreatitis in dogs, and what does it encode? Which breeds?

Answer 51

SPINK-1 gene (serine protease inhibitor, Kazal type 1).
Encodes pancreatic secretory trypsin inhibitor (PTSI).
PTSI/SPINK-1 binds to trypsin & keeps it in inactive form (trypsinogen) > so prevents early activation of trypsin & autodigestion.
Mini Schnauzers.

(Also can get genetic mutations of trypsinogen (leading to resistance to hydrolysis)

Question 52

Drugs & toxins associated with canine pancreatitis?
What infectious agent is commonly associated with pancreatitis in dogs?

Answer 52

Idiosyncratic - azathioprine, L-aspar, clomipramine, meglumine antimionate, phenobarbitone, KBr, combo phenobarb/KBr
True risk factor - sulphonamides
Toxicity (rare) - Zn, lily
Babesia (rossi&raquo_space; gibsoni)

Question 53

Stimuli for zymogen activation > autoactivation of pancreatic enzymes?

Answer 53

• Post-prandial enterokinase release & entry into portal circulation
• Bile reflux into pancreatic ducts or due to duodenal obstruction
• Obstruction of pancreatic acinar cells/ducts
• Thrombin release during bacterial toxemia, ischemia, hypoxia
• Oxidative stress
• ROS (produced in proinflammatory response)
• Hypotension (decreased pancreatic blood flow)
• Cathepsin B (protease; trypsinogen activator)
• Acute hyperCa (rare; possible MOA - Ca deposition in the pancreatic duct > Ca activates trypsinogen)

Question 54

Which cells is implicated in the development of pancreatic fibrosis?

Answer 54

Pancreatic stellate cells (peri-acinar) - role in regulating ECM production.
CCK & oxidative stress also sensitise acinar cells to injury & necrosis

Question 55

Cats with pancreatitis - what associated condition may develop that is of major concern?
1 biochemical marker that is a negative prognostic indicator?

Answer 55

Often associated with SI and/or liver disease.
Hepatic lipidosis.
Vit B12 & vit K deficiencies, hypoK common.

Ionized hypoCa (not in dogs)

Question 56

Based on the ACVIM consensus statement, what are the benefits & recommendations for anti-inflammatory/ immunosuppressive therapy for cats with severe pancreatitis?

Answer 56

Cats that are not hyperglycemic:
- AI doses (0.5-1mg/kg PO q24hr tapering), but some recommend IS doses (2mg/kg q12h x5d then 1mg/kg q12h for 6 wks tapering)
Hyperglycemic cats:
- Cyclosporine 5mg/kg PO q24hr for 6 wks. Risks of unmasking latent toxoplasmosis (long term high dose).
Re-evaluate & recheck spec FPL after 2-3 weeks. If improving continue slow taper.

Question 57

When should surgical treatment of EHBDO be considered?

Answer 57

• Acholic faeces (indicates complete biliary obstruction)
• Failure of icterus to improve >10d (in humans med tx pursued provided resolves within a month)
• GB rupture

Question 58

Breeds predisposed to chronic hepatitis & lobular dissecting hepatitis? Which breeds tend to have earlier onset of disease?

Answer 58

ACVIM consensus
Bedlington Terrier, Dobers, Labs, Dalmatians, Cockers, Eng Springer Spanels, WHWT, Standard Poodles
Cockers & Standard Poodles also for lobular dissecting hepatitis
Dalmatians, Dobers, Eng Springer Spaniels usually younger

Question 59

What molecular biomarker is more sensitive than ALT for dogs with chronic hepatitis?
Which clin path abnormalities are negative prognostic factors?

Answer 59

microRNA-122
HyperBIL, increased APTT/PT, hypoalb, not ALT incr.
Ascites (except Cockers), more severe fibrosis
Overall MST 561d, 22d with ascites (likely cirrhosis)

Question 60

What is the potential impact of sampling regenerative nodules & fibrotic regions on interpreting hepatic copper concentrations?

Answer 60

Both may underestimate Cu

Question 61

Deficiency in ….. may be associated with chronic hepatitis in affected Cocker Spaniels?

Answer 61

alpha-1 anti-trypsin (protease inhibitor) deficiency (accumulation of abnormal A1AT in hepatocytes)

Question 62

List 3 treatment options for copper chelation in dogs with copper storage hepatopathy? MOA & AE?

Answer 62

1. D-penicillamine
- Binds Cu in blood to form water-soluble complexes > increased urinary excretion
- Increases metallothionein in hepatocytes (detoxifies intracellular Cu&raquo_space; excreted in urine) & enterocytes (increases faecal elimination).
- Anti-inflam (reduce T cell activity) + anti-fibrotic effects (reduce collagen X-linking)
- AE: GI signs common, proteinuria (glomerulonephritis), skin eruptions (rare)

2. Zinc
   - Interferes with Cu absorption in the GIT via inducing metallothionein
   - Don’t give with D-pen (latter binds Zn)
   - AE: GI signs common
3. Dietary copper restriction (prescription diets with <0.12mg/100kcal)

+/- SAME/vit E (for Cu-associated oxidative injury)

Question 63

What renal changes may occur with hepatic copper toxicosis? Do these improve with treatment?

Answer 63

Proximal tubular dysfunction > Fanconi-like syndrome. Euglycemic glucosuria, aminoaciduria, granular casts in some dogs.
Yes resolved after copper chelation therapy.

Question 64

How can the measurement of protein C activity be useful in the diagnosis of hepatobiliary disease in dogs?

Answer 64

Differentiation of congenital PSS from PHPV/MVD
Protein C activity >70% in MVD (marked MVD can have borderline levels)
<70% in cPSS, increased to >70% after successful shunt attenuation

Question 65

What coagulation abnormalities on TEG are common in dogs with:
1) Congenial PSS
2) Chronic hepatitis
3) Acute liver failure
4) Biliary disease (GBM)?

Answer 65

CPSS - hypercoagulable (decreased protein C & AT; incr vWF & FVIII). High fibrinogen with high G on TEG > more likely to develop HE (pro-inflammatory state > thrombosis)

CH - hyperfibrinolytic & hypocoagulable with cirrhosis (decr platelets, incr PT/PTT, decr fibrinogen)

Acute liver failure - hyperfibrinolytic (decr protein C & AT, incr APTT, decr platelets)

Biliary dz/GBM: hypercoagulable

Question 66

Contraindications for liver biopsies?

Answer 66

• PT/APTT > 1.5x URI
• Platelets <50-80K
• BMBT >4mins (dogs), >3.3mins (cats)
• Anemic PCV <30%
• Fibrinogen <100mg/dL (<50% lower RI)
• vWF activity <50%
• Ascites (relative contraindication; purported incr bleeding risk & more challenging to do lap bx)
• Infectious dz (may spread by bx)
• Presumed HSA (go for excisional bx)
• Other co-morbidites making patient unstable for GA

Question 67

What is the main stimulus for hepatic fibrosis formation?

Answer 67

Transforming growth factor-b = most potent fibrogenic inflammatory cytokine, pdtn by Kupffer cells. (other cytokines e.g. PDGF)
Activation of hepatic stellate cells > express smooth muscle-specific a-actin & secrete high-density matrix and collagen into the space of Disse.

Question 68

Scottish Terriers with vacuolar hepatopathy are at increased risk of acquiring what disease? What is the pathogenesis behind vacuolar hepatopathy?

Answer 68

Hepatocellular carcinoma.
50% dogs have signs of HAC, but variable adrenal function test results (increased progesterone & androstenedione post ACTH stim).

Question 69

What are reported causes of destructive cholangitis in dogs? What similar clinical sign does it share with bile duct obstruction?

Answer 69

Idiosyncratic reaction to TMPS, canine distemper, some hepatotoxins.
Causes v severe intra-hepatic cholestasis & icterus –> acholic faeces.
Histo - biliary epithelium necrosis