17 January 2010

Antiphospholipid Antibody Syndrome in Children



Antiphospholipid Antibody Syndrome in Children
By:Jill Glassberg Azok
Grand Rounds
January 23, 2009

Case: OL

* HPI: 2 yo female with Trisomy 21, Tetralogy of Fallot
o 7/9/08: surgical repair of TOF
o 7/31: re-exploration of surgical wound due to wound dehiscense, cultures +pseudomonas
o 7/31: developed rash on buttocks, trunk, described as “red, circular spots”; initially thought to be Candida
+ Over the next 2 wks, developed petechiael rash of her trunk, feet
+ Rash became diffuse erythroderma with resolution of petechiae
o 8/15: returned to OR for exploration of sternal wound due to fever, respiratory distress, and rash; no evidence of infection
o 8/22: returned to OR sternal non-union
+ cultures +corynebacterium and enterococcus facaelis


* PMHx
o DOL 3: TE fistula repair
o DOL 9: modified BT shunt
o Post-op course complicated by thrombus in iliac and aorta, requiring thrombectomy
o Hypothyroidism
o Trisomy 21
o Tetralogy of Fallot with pulmonary atresia
o Chronic lung disease requiring tracheostomy and ventilator
Labs
* Lupus anticoagulant: positive
* Russel viper venom test: negative
* Cardiolipin antibody: positive
o IgM: indeterminate, IgA/IgG: negative
* Beta-2-Glycoprotein-I
o IgM: negative, IgA/IgG: positive
* Phosphatidylserine antibodies
o IgA, IgG, IgM-negative
* Skin biopsy
o Marked hemorrhage in the superficial dermis; prominent fibrin thrombi with white blood cells occluding the vessels of the superficial vascular plexus.
o Given the occlusion and lack of inflammation around the vessels, we favor the extravasation of red blood cells is secondary to the occlusion and not secondary to a vasculitis.

Hospital Course
* Diagnosed with Catastrophic Antiphospholipid Antibody Syndrome: Treated with IVIG 5mg/kg
* 8/26: Decreased perfusion, increased lactate, decreased urine output, firm abdomen, guaic positive stools
o KUB: pneumatosis with possible portal venous gas formation
o Taken To OR for concern for necrotizing enterocolitis;
o Exploratory laparotomy and ileocolic resection
o Small intestine had diffuse areas of necrotizing enterocolitis with poor perfusion
o Right colon and the transverse colon were distended with evidence of full-thickness injury and vessel thrombosis
o Returned to CICU on inotropic support, broad spectrum antibiotics, both chest and abdomen were open
* 8/28 worsened clinically: Back to OR
o Small bowel was necrotic with multiple areas of full-thickness injury.
o The remaining portion of the colon down to the level of the rectus was also necrotic.
o Thrombi in the distal vessels and at the end branches of the mesenteric vessels
o She had a complete colectomy with resection of most of her small bowel
* 8/29: family decided to withdraw care: patient expired
* Autopsy: Cause of death listed as catastrophic antiphospholipid antibody syndrome

Antiphospholipid Antibody Syndrome
* Multisystem autoimmune disease
* Most common cause of acquired thrombophilia
* History
o 1906: antiphospholipid antibody discovered in patients with syphilis, complement-fixing antibody that reacted with extracts from bovine hearts
o 1952: Conley and Hartmann described circulating anticoagulant in patients with Lupus
o 1963: Bowie associated the anticoagulant with thromboembolic events
* Epidemiology
o Most common in young to middle-age adults
o Can occur in children and elderly
o More common in females

* Diagnosis
o At least one antiphospholipid antibody
o At least one clinical manifestation
* May be primary or secondary


CLINICAL CRITERIA
1. Vascular thrombosis: One or more clinical episodes of arterial, venous, or small vessel thrombosis, in any tissue or organ.
2. Pregnancy morbidity

A. One or more unexplained deaths of a morphologically normal fetus at or beyond the tenth week of gestation, with normal fetal morphology documented by ultrasound or by direct examination of the fetus, or

B. One or more premature births of a morphologically normal neonate at or before the thirty-fourth week of gestation because of severe preeclampsia or eclampsia, or severe placental insufficiency, or

C. Three or more unexplained consecutive spontaneous abortions before the tenth week of gestation, with maternal anatomic or hormonal abnormalities and paternal and maternal chromosomal causes excluded


LABORATORY CRITERIA

1. aCL of IgG and/or IgM isotype in blood, present in medium or high titer, on two or more occasions at least 6 weeks apart, measured by a standardized ELISA for β2-GPI–dependent aCL.

2. Lupus anticoagulant present in plasma, on two or more occasions at least 6 weeks apart, detected according to the guidelines of the International Society on Thrombosis and Hemostasis (Scientific Subcommittee on Lupus Anticoagulant/Phospholipid-Dependent Antibodies), in the following steps:

A. Prolonged phospholipid-dependent coagulation demonstrated on a screening test (eg, activated partial thromboplastin time [aPTT], kaolin clotting time, dilute Russell's viper venom time, dilute prothrombin time, Texarin time)

B. Failure to correct the prolonged coagulation time on the screening test by mixing with normal platelet-poor plasma

C. Shortening or correction of the prolonged coagulation time on the screening test by the addition of excess phospholipid

D. Exclusion of other coagulopathies (eg, factor VIII inhibitor or heparin) as appropriate

Clinical Manifestations
* Vascular thrombosis: arterial and venous
* Skin: Levido reticularis
* Recurrent pregnancy loss
* Neurologic: TIA, stroke, migraine, chorea, seizures, optic neuritis
o Sneddon Syndrome: stroke, levido reticularis, hypertension
* Cardiac: Coronary artery disease, premature atherosclerosis, vegetations
* Renal: thrombotic microangiopathy, renal vein thrombosis, renal infarction, renal artery stenosis with hypertension, increased allograft vascular thrombosis, and reduced survival of renal allografts
* Pulmonary: PE, pulmonary hypertension
* GI: Budd-Chiari syndrome, intestinal ischemia and infarction, colonic ulceration, esophageal necrosis and perforation, hepatic infarction, acalculous cholecystitis with gallbladder necrosis, and mesenteric and portal vein thrombosis
* Hematologic: thrombocytopenia, TTP/HUS, hemolytic anemia

Antiphospholipid antibodies
* Antiphospholipid antibodies present in young, healthy controls
o Studies of healthy blood donors
+ Lupus anticoagulant in 8%
+ IgG anticardiolipin in 6.5%
+ IgM anticardiolipin in 9.4%
+ <2% of healthy blood donors with elevated anticardiolipin antibody still had elevated level 9months later
o Incidence increases with age and coexisting chronic disease
* Among patients with thrombosis, prevalence of antiphospholipid antibodies is 4 to 21%
* Increasing risk of thrombosis among those with higher antibody titers

* Lupus anticoagulant: most specific
o Functional assay, measures ability to prolong clotting time
o aPTT, Russel viper venom test, kaolin clotting time
o Meta-analysis showed the odds ratio of lupus anticoagulant for stroke: 11 compared to 1.6 for anticardiolipin
* Anticardiolipin antibodies- most sensitive
* Anti-b2 Glycoprotein I antibodies
* Other antibodies of unclear significance: prothrombin, annexin V, phosphatidylserine, phosphatidylinositol, phosphatidylcholine
* Some anti-cardiolipin antibodies require presence of the plasma phospholipid-binding protein b 2-glycoprotein I in order to bind to cardiolipin
* People with syphilis or infectious diseases, antibodies bind directly to anticardiolipin, independent of /inhibited by b 2-glycoprotein-I
* Autoimmune anticardiolipin antibodies directed against phospholipid-binding protein, not phospholipid itself

Pathogenesis Theories
* Interfere with phospholipid-binding proteins involved in the regulation of the clotting cascadeprocoagulant
* Activation of endothelial cellsincreased expression of cell-surface adhesion molecules and increased secretion of cytokines and prostaglandins
* Oxidant-mediated injury of vascular endothelium
* Platelet activation

Drug Induced aPLs
* Mediations reported
o Phenothiazines
o Phenytoin
o Hydralazine
o Procainamide
o Quinidine
o Dilantin
o Ethosuximide
o Alpha-interferon
o Amoxicillin
o Chlorothiazide
o Oral contraceptives
o Propranolol
* Usually transient
* Associated with IgM
* Rarely associated with thrombosis
* Mechanism unknown

Significance of aPLs
* No history of thrombosis and positive aPL: Risk of new thrombosis <1%
* History of thrombosis and positive aPL: Risk of new thrombosis >10% in first year if anticoagulation stopped within 6 months

A systematic review of secondary thromboprophylaxis in patients with antiphospholipid antibodies
Ruiz-Irastorza G Database of Abstracts of Reviews of Effects 2008

* Sixteen studies were included (n=1,740)
* Thrombosis recurrence rates among untreated patients: 19 to 29% per year
* Rates of major bleeding varied widely, ranging from 0.57 to 10% per year. Seventy-four per cent of bleeding episodes occurred in patients with an INR ≥3.0
* Eighteen deaths were reported to be directly related to recurrent thromboses and one due to bleeding. Ten patients in one study died as a result of the presenting thrombosis
* Patients with definite APS and arterial and/or recurrent thrombosis are at high risk of recurrent events. Most thrombotic events in patients on warfarin occur at an INR <3; recurrences are infrequent among those with an INR of 3.0 to 4.0. Patients with venous embolism or stroke and a single positive aPL that does not persist are at relatively low risk of recurrent thrombosis.
* Recommendations: after a first venous thrombosis, patients with APS should be treated with warfarin at an INR of 2.0 to 3.0; those with arterial or secondary thrombosis should be treated with warfarin at an INR >3.0. Patients with venous thrombosis or stroke and a single positive aPL test should be retested, and should be treated no differently from other patients unless the antibody persists.

Pediatric Antiphospholipid Syndrome: Clinical and Immunologic Features of 121 Patients in an International Registry
* 121 cases of antiphospholipid antibody syndrome in children in the European registry
o Mean age of onset: 10.7 years
o Slightly more common in females, 1.2:1
o 60 (49.5%) had underlying autoimmune disease
o 72 (60%) had venous thrombosis
o 39 (32%) had arterial thrombosis
o 81% had positive anticardiolipin antibodies
o 67% had positive anti-b2-glycoprotein I antibodies
o 72% had positive Lupus anticoagulant

Unique to Pediatric Population
* Lack of prothrombotic risk factors which are present in adults, ie cigarette smoking
o Frequency of vascular thrombosis lower
* Increased incidence of infection-related antiphospholipid antibodies
o Parvovirus B19, cytomegalovirus, varicella-zoster virus, HIV, streptococcal and staphylococcal infections, gram negative bacteria, mycoplasma pneumoniae
* Higher frequency of Evan’s syndrome, Raynaud’s, migraines, and chorea
* Decision-making for long term anticoagulation

Neonatal APS
* Due to transplacental passage of maternal aCL, disappear over 6months
* In pediatric age group, neonatal period highest risk for thrombosis
o Decreased Protein C, Protein S, and antithrombin
o Elevated Factor VIII and von Willebrand factor
* Despite this, very low risk of thrombosis

Catastrophic APS
* Multiple, simultaneous vascular occlusions throughout body
o Widespread microthrombi in multiple vascular bedsMassive thromboembolism
o Clinical involvement of at least 3 organ systems over days to weeks
o Histopathologic evidence of occlusions of small and large blood vessels
o Most common organs: kidney>lung>CNS>heart>skinmultiorgan failure
o DIC in 25%
o Respiratory failure, stroke, abnormal liver enzymes, renal insufficiency/failure, adrenal insufficiency, cutaneous infarcts
* Precipitating factor in 55%: Most common is infection
* Usually primary APS
* Treatment
o Treat precipitating factor if present
o Anticoagulation
o Steroids
o IVIG
o Plasma exchange
* Mortality > 50%

Antiphospholipid Antibody Syndrome in Children .ppt

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13 January 2010

Amino Acid Metabolism



Amino Acid Metabolism
by:Hanley N. Abramson
Professor of Pharmaceutical Sciences
Wayne State University

December 2009

Dynamics of Protein And Amino Acid Metabolism
Dietary Proteins Digestion to Amino Acids
Digestion of Proteins
Stomach: Pepsinogen Pepsin (max. act. pH 2)
Small Intestine: Trypsinogen Trypsin
Trypsin cleaves:
Chymotrypsinogen to chymotrypsin
Proelastase to elastase
Procarboxypeptidase to carboxypeptidase
Aminopeptidases (from intestinal epithelia)

Enteropeptidase
Lumen
Amino Acids Oligopeptides
Intestinal Absorption
Oligopeptides
Amino Acids
Peptidases
Blood
Transport
Protein
Incorporation of NH4+ Into Organic Compounds
Carbamoyl
Phosphate
Synthase I
(CPS-I)
Glutamate
dehydrogenase
a-Ketoglutarate
Glutamate
TCA Cycle
mitochondria
Glutamine
Glutamate
Glutamine
Synthase
Mg++
N of glutamine donated to other compounds in synthesis of purines, pyrimidines, and other amino acids
Biosynthesis of Amino Acids: Transaminations
Glutamate a-Ketoglutarate
Oxaloacetate Aspartate
Glutamate-Pyruvate
Aminotransferase
(Alanine Transferase ALT)
Glutamate-Oxaloacetate
Aminotransferase
(Aspartate Transferase AST)
Blood levels of these aminotransferases, also called transaminases, are important indicators of liver disease
Metabolic Classification of the Amino Acids
* Essential and Non-essential
* Glucogenic and Ketogenic
Non-Essential Amino Acids in Humans
* Not required in diet
* Can be formed from a-keto acids by transamination and subsequent reactions
* Alanine
* Asparagine
* Aspartate
* Glutamate
* Glutamine
* Glycine
* Proline
* Serine
* Cysteine (from Met*)
* Tyrosine (from Phe*)
* Essential amino acids
Essential Amino Acids in Humans
* Required in diet
* Humans incapable of forming requisite carbon skeleton
* Arginine*
* Histidine*
* Isoleucine
* Leucine
* Valine
* Lysine
* Methionine
* Threonine
* Phenylalanine
* Tryptophan

* Essential in children, not in adults

Glucogenic Amino Acids
* Metabolized to a-ketoglutarate, pyruvate, oxaloacetate, fumarate, or succinyl CoA
Phosphoenolpyruvate Glucose
* Aspartate
* Asparagine
* Arginine
* Phenylalanine
* Tyrosine
* Isoleucine
* Methionine
* Valine
* Glutamine
* Glutamate
* Proline
* Histidine
* Alanine
* Serine
* Cysteine
* Glycine
* Threonine
* Tryptophan

Ketogenic Amino Acids
* Isoleucine
* Leucine *
* Lysine *
* Threonine
* Tryptophan
* Phenylalanine
* Tyrosine

Amino Acids Formed From a-Ketoglutarate
Transamination or
Glutamate
Urea Formation
Blood Urea Nitrogen
Synthesis of Nitric Oxide
Nitric oxide synthase (NOS)
Nitric Oxide
Conversion of Serine to Glycine
Sulfur-Containing Amino Acids
Homocysteine
Homocysteinuria
High blood levels of homocysteine associated with cardiovascular disease
Methionine Metabolism: Methyl Donation
Pneumocystis carinii infectons
Creatine and Creatinine
Normal Utilization of Phenylalanine ....

Amino Acid Metabolism.ppt

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Protein Digestion and Absorption



Protein Digestion and Absorption

* Dietary proteins, with few exceptions, are not absorbed.
* Dietary proteins, with few exceptions, are not absorbed.
* They must be digested first into amino acids or di- and tri-peptides.
* Dietary proteins, with few exceptions, are not absorbed.
* They must be digested first into amino acids or di- and tri-peptides.
* Through the action of gastric and pancreatic proteases, proteins are digested within the lumen into medium and small peptides (oligopeptides).


Digestion of protein - hydrolysis
Protein digestion begins in stomach
Pepsin - inactive precursor pepsinogen
Active @ pH 2-3, inactive pH>5
Secretion stimulated by acetylcholine or acid
Only protease which can break down collagen
Action terminated by neutralisation by bicarbonate in duodenum.
N.B. **All proteases (stomach & pancreatic) secreted as inactive precursors. Most protein digestion occurs in the duodenum/jejunum

Activation of pancreatic proteases
Trypsinogen
Trypsin
Enterokinase
Trypsinogen
Chymotrypsinogen
Proelastase
Procarboxypeptidase
Trypsin
Chymotrypsin
Elastase
Carboxypeptidase
Active proteases inactivated by trypsin
peptidases
aminopolypeptidase
transporters
amino acids
Di/tri peptides
Cytoplasmic peptidase

Pancreatic enzymes
Essential for digestion
essential for life
Proteases
Inactive form
Activated in gut
Acinar cells
Lipases Amylases
Active enzymes

Pancreatic Enzymes
* The bulk of protein digestion occurs within the intestine due to the action of pancreatic proteases.

Pancreatic Proteases
* The two primary pancreatic proteases are trypsin and chymotrypsin.
* They are synthesized and packaged within secretory vesicles as inactive proenzymes:
trypsinogen chymotrypsin
* The two primary pancreatic proteases are trypsin and chymotrypsin.
* They are synthesized and packaged within secretory vesicles as inactive proenzymes:

trypsinogen chymotrypsin
The secretory vesicles also contain a trypsin inhibitor to serve as a safeguard against trypsinogen converted to trypsin.

Other Pancreatic Proteases
* Procarboxypeptidase  carboxypeptidase
* Proelastase  elastase

Trypsin
* Trypsinogen is converted to trypsin by the enzyme enterokinase (enteropeptidase) secreted by cells lining duodenum.
* Trypsinogen is converted to trypsin by the enzyme enterokinase (enteropeptidase) secreted by cells lining duodenum.
* Trypsin then activates the conversion of other zymogens from their inactive to active forms.
* Trypsinogen is converted to trypsin by the enzyme enterokinase (enteropeptidase) secreted by cells lining duodenum.
* Trypsin then activates the conversion of other zymogens from their inactive to active forms.
* Inhibition of trypsin will slow activation of other proteases.
* Trypsin catalyzes the splitting of peptide bonds on the carboxyl side of lysine and arginine residues.
* It has a pH optimum of 7.6 to 8.0 (alkaline).
* Classified as a serine protease (serine and histidine at the active site.

Trypsin, Chymotrypsin
* Similar chemical compositions
* Chief differences are specificity of action:
trypsin – lysine, arginine
chymotrypsin – tyrosine, phenylalanine, tryptophan, methionine,leucine
(aromatic or large hydrophobic side chains)

Lock and Key Model of Enzyme Activity
Visualization of the Lock and Key Model of Enzyme Function

Lock Key Enzyme Catalysis
* The “Active Site” contains:
* A shape that fits a specific substrate(s)
* Side chains that attract (chemically) the substrate
* Side chains that are positioned to speed the reaction

Enzyme Catalysis
* -OH of serine 195 attacks C=O of peptide bond. Histidine 57 donates a proton to the N of the peptide bond leading to cleavage and acylation of the enzyme. Asp-102 is also involved.

Carboxypeptidase COO- terminal peptide bond
* Hydrolysis occurs most readily if the COO- terminal residue has an aromatic or bulky aliphatic side chain.
* Binding of a typical substrate results in a rearrangement of the active site (induce fit). Glutamate-270, Arginine-145, Arginine-127, Tyrosine-248 are important at the active site.

Trypsin Inhibitors
* Trypsin (protease) inhibitors are found naturally in many seeds, particularly legumes such as soy, peas, other beans.
* heat labile, heat stable
* Osborne and Mendel (1917) – soybeans need to be heated to support growth in rats
* Kunitz inhibitor, Bowman-Birk inhibitor
* Both are inactivated during moist heat treatment.
* Protease inhibitors are proteins which bind to the enzyme, rendering them inactive.
* Symptoms include pancreatic hypertrophy due to stimulated secretory activity.

Absorption of peptides and amino acids
Transport at the brush border
1. Active transport by carrier.
2. Mostly dependent on Na+ gradient - co-transport similar to that for glucose
3. Some amino acids (basic, and neutral with hydrophobic side chains) are absorbed by facilitated diffusion
Protein assimilation affected by - Pancreatitis, congenital protease deficiencies, deficiencies of specific transporters

Absorption of Amino Acids
* The transporters bind amino acids only after binding sodium.
* The fully loaded transporter undergoes a conformational change that dumps Na+ and the amino acid into the cytoplasm. The transporter then reorients back to its original form.

Absorption of Amino Acids
* Absorption of amino acids is dependent on the electrochemical gradient of Na+ across the epithelium.
* The basolateral membrane of the enterocyte contains additional transporters which export amino acids from the cell into the blood (not dependent on sodium gradients).

Absorption of Peptides
* There is virtually no absorption of peptides longer than three amino acids but there is abundant absorption of di- and tri-peptides, probably by a single transport molecule.
* The vast bulk of di- and tri-peptides are digested into amino acids by cytoplasmic peptidases.

Absorption of Intact Proteins
* Absorption of intact proteins occurs rarely.
* Very few proteins can get through the gauntlet of soluble (lumen) and membrane-bound proteases intact.
* “Normal” enterocytes do not have the transporters neededt to carry proteins across the plasma membrane and they can’t permeate tight junctions.

Absorption of Intact Proteins
* Shortly after birth, neonates can absorb intact proteins.
Absorption of Intact Proteins
* Shortly after birth, neonates can absorb intact proteins.
* Most of these intact proteins are immunoglobulins which can be absorbed from the very first milk (colostrum) and this imparts early neonatal passive immunity.

Absorption of Intact Proteins
* Shortly after birth, neonates can absorb intact proteins.
* Most of these intact proteins are immunoglobulins which can be absorbed from the very first milk (colostrum) and this imparts early neonatal passive immunity.
* “Closure” is when the small intestine loses the capacity to absorb intact proteins.

Protein Requirements
* Maintenance = nutritional requirements to stay alive (does not require positive BW gain)
* Growth = positive tissue accretion
* Reproduction = tissue specific growth related to reproduction, reproductive function (milk, eggs, reproductive tissue)

How do you express a protein requirement ?
* Protein percent of the diet
* Amino acid percent of the diet
Growth Will Dictate Feed Intake
Intake Will Dictate Actual Requirement
* Protein percent of the diet
* Amino acid percent of the diet
* Amino acid percent of total protein
How do you express a protein requirement ?

* Protein percent of the diet
* Amino acid percent of the diet
* Amino acid percent of total protein
* Digestible protein percent of the diet

Digestible Protein Estimates
Digestible Amino Acid Determination
How do you express a protein requirement ?
* Protein percent of the diet
* Amino acid percent of the diet
* Amino acid percent of total protein
* Digestible protein percent of the diet
* Ideal Protein ratios (relationships among amino acids)
Economics of Protein Nutrition
Caloric cost of protein deposition
Amino Acid Balance
Dietary Protein/Amino Acid Balance
Protein Quality Evaluation
Protein Efficiency Ratio
Comparison of Protein Sources
Commercial Application of PER

Protein Digestion and Absorption.ppt

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