Unit 1 SIGS

Question 1

What are the CFTR gene mutation classes?

Answer 1

Class I - no protein - channel not made at all
Class II - no transport - channel not transported to cell membrane
Class III - no function - channel on cell membrane but doesn’t work
Class IV - less function - channels work but poor/decreased function
Class V - less protein - not enough channels made
Class VI - not stable - channels work but aren’t stable, need frequent replacement

Question 2

Describe the Class I CFTR gene mutation pathophysiology

Answer 2

The result of a nonsense, frameshift or splice-site mutation leads to premature termination of the mRNA sequence –> no protein made –> absence of Cl- channel

Question 3

Describe the Class II CFTR gene mutation pathophysiology

Answer 3

Abnormal post-translational processing of the CFTR protein –> channel unable to move to proper location

Question 4

Describe the Class III CFTR gene mutation pathophysiology

Answer 4

Diminished protein activity in response to intracellular signaling –> fully formed channel but non-functioning

Question 5

Describe the Class IV CFTR gene mutation pathophysiology

Answer 5

CFTR protein has been produced and correctly localized to the cell surface, but rate of chloride ion flow and duration of channel activation after stimulation is decreased from normal

Question 6

Describe the Class V CFTR gene mutation pathophysiology

Answer 6

Decreased concentration of CFTR channels in the cell membrane as a result of rapid degradation.

Question 7

Describe the Class VI CFTR gene mutation pathophysiology

Answer 7

Channel instability leads to rapid turnover and decreased net function

Question 8

Describe the pathway of glycogenesis

Answer 8

Glucose –> (Glucokinase) –> G6P –> Glucose-1-Phosphate –> UDP-Glucose –> linear glycogen –> (branching enzyme) –> branched glycogen –> (Glycogen phosphorylase) –> Limit Dextrin –> (4-a-D-glucanotransferase) –> Modified Limit Dextrin –> (a-1,6-glucosidase) –> Glycogen

Question 9

Discuss the function of Glucose-6-Phosphatase

Answer 9

Converts Glucose-6-Phosphate into glucose

Question 10

What is the inheritance pattern of glycogen storage disease?

Answer 10

Autosomal recessive

Question 11

Describe the importance of dietary therapy in the management of von Gierke disease

Answer 11

Foods rich in fructose or galactose need to be avoided - they need to be converted to G6P before they can be utilized

Cornstarch helps prevent hypoglycemic events

Question 12

Outline the pathophys and clinical presentation of Type I GSD

Answer 12

Von Gierke Disease - mutation on G6PC gene for G6Pase - diminished G6Pase can’t convert Glucose-6-Phospohate into glucose

Clinical presentation:
Hepatomegaly, renomegaly from increased glycogen and lipids
Hypoglycemic tremor, confusion, seizures
Gout
“Doll-like” faces

Question 13

Outline the pathophys and clinical presentation of Type II GSD

Answer 13

Pompe disease - impaired glycogenolysis - defective Lysosomal acid a-1,4 glucosidase –> decrease of branch hydrolysis –> increase glycogen in cardiac muscle - affects tissue

Clinical presentation
Progressive
Failure to thrive, proximal myopathy, exercise intolerance
Hypertrophic cardiomyopathy
Respiratory failure
Early death

Question 14

Outline the pathophys and clinical presentation of Type III GSD

Answer 14

Cori’s disease - impaired glycogenolysis, functional gluconeogenesis

Defective AGL gene –> decrease in debranching enzymes –> increase limit dextrin

Clinical presentation:
Failure to thrive, muscle weakness, cramps
Hepatomegaly, possible cirrhosis or cardiomyopathy

Needs high protein diet with cornstarch supplementation

Question 15

Outline the pathophys and clinical presentation of Type IV GSD

Answer 15

Anderson disease - impaired glycogenesis - defective GBE1 gene –> branching enzyme depletion –> decreased branched glycogen - affects tissue and liver

Clinical presentation:
Failure to thrive
Hepatosplenomegaly
Hypotonia, cardiomyopathy
Peripheral neuropath
Early death

Question 16

Outline the pathophys and clinical presentation of Type V GSD

Answer 16

McArdle disease - impaired glycogenolysis - defective PYGM gene –> decreased muscle phosphorylase

Clinical presentation
Older child/adolescent
Muscle weakness, cramps, exercise intolerance
Rhabdomyolysis, myoglobinuria

Question 17

Outline the pathophys and clinical presentation of Type VI GSD

Answer 17

Hers disease - Impaired glycogenolysis - defective PYGL gene - decreased hepatic phosphorylase –> no debranching of glycogen

Presentation:
Hepatomegaly, hepatic fibrosis
Poor metabolic control –> short stature, delayed puberty, osteopenia, osteoporosis

Question 18

How does Type I GSD affect serum levels of glucose, lactate, uric acid, and lipids?

Answer 18

Decreased plasma glucose levels
Elevated lactic acid levels
Elevated triglyceride levels
Elevated uric acid levels

Question 19

Clinical presentation of Barrett’s Esophagus

Answer 19

Retrosternal burning
Regurgitation with water brash
Worse when supine and after eating

Question 20

How does smoking increase the risk of Barrett’s Esophagus?

Answer 20

Nicotine relaces smooth muscle –> relaxing the lower esophageal sphincter allows gastric juices to get through
Reduced amount of HCO3 in saliva –> decreased acid neutralizing compound
Induces inflammation –> decrease peristalsis –> disrupts clearance of stomach acid from esophagus

Question 21

When does GERD turn into Barret Esophagus?

Answer 21

When there is metaplasia of the distal esophageal –> change from squamous to columnar

Question 22

Explain the pathophysiology of treatment options for Barret esophagus

Answer 22

Antacids - increase pH of stomach acid (neutralize)
Histamine blockers - prevents increase of gastric acid after meals
Proton pump inhibitors - decrease amount of H+ ions pumped into stomach

Question 23

Inheritance pattern of Sickle Cell Disease

Answer 23

autosomal recessive

Question 24

Explain the pathogenesis of Sickle Cell Disease

Answer 24

Sickle cell disease - ɑɑSS (homozygous)
Hemoglobin SC disease - ɑɑSC (double mutation)
Sickle cell trait - ɑɑβS (heterozygous)

Globin S chain –> B missense mutation on C11 (Glu(-) –> Val(0))
Globin C chain –> B missense mutation on C11 (Glu(-) –> Lys(+))

Question 25

Describe the Sickle Cell Disease pathophysiology

Answer 25

In the deoxygenated form of HbS, the valine becomes buried in a hydrophobic pocket on an adjacent beta-globin chain. This joines the molecules together to form insoluble polymers. When enough of these form, it gives rise to the classic sickled shape

Question 26

Outline the clinical presentation of Sickle Cell disease

Answer 26

General anemia features
Vaso-occlusive events - hallmark
Asplenia
Hematuria
Recurring infections (due to loss of splenic function)

Question 27

Most distinguishing clinical feature of Sickle Cell Disease

Answer 27

Acute vaso-occlusion pain

Sickle cells lack elasticity –> adhere to endothelium –> causes vasoocclusion –> stroke, acute chest syndrome (pulmonary hypertension), splenic sequestration

Question 28

How does Sickle Cell Disease affect vital signs?

Answer 28

Lower blood pressure than normal reference ranges

Higher blood pressures are at risk for stroke

Question 29

Diagnostic tests of Sickle Cell Anemia

Answer 29

Hemoglobin electrophoresis - checking for fetal hgb
PBS

Question 30

Justify the use of hydroxyurea therapy for Sickle Cell Disease

Answer 30

Hydroxyurea therapy uses an antineoplastic drug to inhibit ribonucleotide reductase
This inhibits DNA replication and causes cell cycle arrest in S phase
Increased nitric oxide levels and cGMP signaling lead to an increase in HgbF

Question 31

What is the inheritance pattern of hereditary spherocytosis?

Answer 31

** Autosomal dominant **

Question 32

List the laboratory values of HS, and what unique lab finding will you find in a patient with HS?

Answer 32

normal MCV
Increased reticulocytes
Decreased haptoglobin (binding to free-floating hemoglobin)
Increased indirect bilirubin

Increased MCHC

Question 33

Describe the pathogenesis and pathophysiology of HS

Answer 33

Deficiency in one or more proteins - spectrin, ankyrin, band 3, or and/or band 4.2 - within the RBC membrane/cytoskeleton lead to misshapen and fragile RBC.

Lack of adherence between the cytoskeleton and the cell membrane –> RBC loses biconcave shape –> decrease surface area –> anemia

Howell-Jolly bodies –> extravascular hemolysis

Lack of plasticity –> splenic trapping

Question 34

Outline the clinical features of HS

Answer 34

Mild: asymptomatic
Moderate: General anemia features, Jaundice, Splenomegaly, Cholelithiasis
Severe: hydrops fetalis, skeletal deformities, delayed puberty

Question 35

Explain the role of parvo B19 in HS

Answer 35

Parvo B19 infects the bone marrow and uses erythroid progenitor cells to replicate, thus taking them from producing RBC –> causes aplastic crisis in patients with hemolytic anemias who need RBCs to replicate rapidly to replace the damaged RBCs

Question 36

How does HS effect energy levels

Answer 36

RBC hemolysis –> less O2 carrying capacity and distribution throughout the blood –> less O2 available for aerobic metabolism –> decreased ATP production

Question 37

Define the clinical utility and significance of osmotic fragility testing and eosin-5-maleimide (EMA) studies in the diagnosis of HS.

Answer 37

Eosin-5-maleimide binding test - test of choice –> looking for decreased binding between E5M dye and RBC membranes –> binding is quantified using flow cytometry

Osmotic fragility test - measures ability of RBCs to resist hemolysis when exposed to different degrees of salt dilution –> HS more vulnerable to osmotic stress –> will explode in hypotonic solution

Question 38

How do spherocytes differ from normal RBC on PBS

Answer 38

Spherocytes don’t have the biconcave shape so they don’t have the central pallor seen in RBC
Spherocytes may have Howell-Jolly bodies

Question 39

Signs and symptoms of acetaminophen overdose

Answer 39

Nausea, vomiting, pallor, lethargy
Progressive liver impairment
Jaundice

Question 40

Outline pathophysiology of acetaminophen overdose

Answer 40

Majority of acetaminophen metabolized to bile –> rest (normally small amount) processed via CP450 into NAPQI –> glutathione inactivates NAPQI –> too much acetaminophen depletes glutathione stores –> NAPQI build up –> oxidative stress –> hepatocyte injury/liver necrosis

Question 41

How does treatment prevent acetaminophen overdose

Answer 41

N-acetylcysteine provides sulfur to aid in glutathione synthesis

Activated charcoal absorbs newly ingested acetaminophen to prevent absorption into blood stream

Question 42

Why does acute alcohol intake delay acetaminophen metabolism/overdose?

How does chronic alcohol intake accelerate acetaminophen metabolism?

Answer 42

Alcohol is a competitive inhibitor to acetaminophen of the CP450 enzyme.

Chronic alcohol use induces hepatic microsomal enzymes that result in the accelerated metabolism of acetaminophen.

Question 43

What is the virulence factor of Staphylococcus aureus

Answer 43

Protein A - binds to macrophage-binding section of IgG antibody which prevents the macrophage from binding and destroying the pathogen

Question 44

Pt presents with a poorly defined lesion with cutaneous lymphatic edema. The area is warm, tender, and red around the lesion. Pt states it started as an itchy bug-bite but has turned into this over the last 2 or 3 days.

Labs show increased neutrophils with decreased monocytes, and a negative Catalase test. What is the DDx and what is the treatment?

Answer 44

Cellulitis treated with broad spectrum ABX

Question 45

What cancers are most common in children with Down Syndrome and why?

Answer 45

Under 5yo - Acute myelogenous leukemia (AML)

Older than 5yo - Acute lymphoblastic leukemia (ALL)

Question 46

Describe the clinical presentation of Cystic Fibrosis

Answer 46

Infants: meconium ileus, failure to thrive, malabsorption

Adults: distal intestinal blockages, pulmonary emphysema - dilation of air spaces, male infertility (vas deferens doesn’t form), finger/toe clubbing, poor growth

Question 47

Identify and describe the tests used for diagnosis of CF

Answer 47

X-ray of abdomen with contrast - Neuhauser sign (soap bubble appearance)

Chest X-ray - pulmonary emphysema (dilation of alveoli)

Sweat chloride test - defective ATP-gated Cl- channels can’t reabsorb Cl- from sweat glands, causes excess Cl-, Na+ and water –> 60mmol/L or greater of NaCl

CF screening panel

Question 48

Why might a newborn with CF show a false negative on neonatal CF screening?

Answer 48

Screening checks for increased IRT, which may also be increased if babies are premature, a carrier of the mutation, or had a stressful delivery.

Question 49

Describe the pathogenesis of CF

Answer 49

Mutation of the CFTR gene on Chromosome 7 causes mutation of the ATP-gated Cl- channel proteins on the surface of epithelial cells.

Leads to decreased secretion of Cl- and increased resorption of Na+ into cellular space. Sodium reabsorption –> increased water resorption –> thicker mucus secretions

Pathway: Ga(s) –> +Adenylyl cyclase –> cAMP –> PKA –> CFTR

Question 50

Explain the different karyotypic findings associated with Turner Syndrome

Answer 50

45XO, 45X/46XX, 45X/46XY, 45X/47XXX

Question 51

Discuss the process of male and female gametogenesis and fertilization

Answer 51

Spermatogenesis : spermatogonium (2n) –> primary spermatocyte (2n) –> secondary spermatocyte (1n) –> spermatid (1n) –> sperm (spermatids with tails)

Oogenesis : Oogonium (2n) –> primary oocyte (2n) –> secondary oocyte (1n) + polar body –> ootid (1n) + polar body (first polar body –> 2 polar bodies) –> ovum (1n) + 3 polar bodies

Question 52

Describe anaphase lag and how it contributes to chromosomal abnormalities

Answer 52

Anaphase lag is the failure of a spindle fiber to pull a chromatid apart from the midline –> chromatid stays separated from the rest of the chromosomes while nuclear envelope forms –> lagged chromatid stuck outside nuclear envelope –> chromosome destroyed = monosomy

Question 53

Explain the components and values of the Quad test seen in Down Syndrome

Answer 53

Decreased AFP (alpha fetal protein)
Decreased Unconjugated estriol
Increased Inhibin A
Increased hCG (DS is the only disorder with increase in hCG)

Question 54

Describe the major medical complications of Down Syndrome

Answer 54

Congenital heart defects - AVSD most common
Hirschsprung’s disease - ENS missing from end of bowel
Hypogonadism, decreased fertility
Cancer
Early onset Alzheimer’s - amyloid production gene upregulated on extra chromosome

Question 55

Pathogenesis of TTP

Answer 55

95% of cases acquired by IgG autoantibodies of ADAMTS13

5% - gene mutation –> depletion of ADAMTS13 antigen –> Upshaw-Shulman disease –> found in families with consanguinity

Question 56

Pathophysiology of TTP

Answer 56

ADAMTS13 function is to cleave vWF to regulate clotting

Mutation of ADAMTS13 causes buildup of vWF factor –> vWF accumulates on endothelial cells –> increased platelet adhesion –> microthrombi –> mechanically shearing of RBC and blockage of small vessels –> schistocytes, end organ ischemia

Question 57

Clinical features of TTP and common complications

Answer 57

Thrombocytopenia
Microangiopathic hemolytic anemia
Petechiae
Jaundice
Neurological defects

Complications: stroke, seizures, hemorrhagic colitis, bowel necrosis, ischemia, renal failure

Question 58

Lab findings of TTP

Answer 58

↓ platelets (thrombocytopenia)
↓ hemoglobin (hemolysis - free floating hemoglobin)
↓ haptoglobin (hemolysis)
↑ reticulocytes (replenishing RBC)
↑ LDH (hemolysis - RBC use lactic acid pathway to make ATP)
↑ bilirubin (hemolysis - heme metabolism)
↑ D-dimer

Coag: ↑ Bleeding time, Normal PT, normal or slightly ↑ PTT
PBS: schistocytes, low platelets

Question 59

Lab findings of Disseminated Intravascular Coagulation (DIC)

Answer 59

↓ platelets
↓ Fibrinogen
↑ D-dimer
↑ LDH

Coag: ↑ Bleeding time, ↑ PT, ↑ PTT
PBS: Schistocytes

Question 60

Lab findings of Hemolytic Uremic Syndrome

Answer 60

↓ platelets (thrombocytopenia)
↓ hemoglobin (hemolysis - free floating hemoglobin)
↓ haptoglobin (hemolysis)
↑ reticulocytes (replenishing RBC)
↑ LDH (hemolysis - RBC use lactic acid pathway to make ATP)
↑ bilirubin (hemolysis - heme metabolism)
Normal D-dimer
↑ WBC

Coag: ↑ Bleeding time, Normal PT, normal or slightly ↑ PTT
PBS: schistocytes, low platelets

Question 61

Pathogenesis of HUS

Answer 61

Infection of E. Coli Shiga Toxin cause mucosal inflammation –> facilitates bacterial toxins entering circulation –> toxins cause endothelial cell damage, especially in renal structures –> damages endothelial cells secrete cytokines –> vasoconstriction and platelet microthrombus formation (intravascular coagulopathy) –> thrombocytopenia –> RBCs mechanically destroyed by microthrombi –> hemolysis and end organ ischemia

Question 62

Justify the use of plasmapheresis rather than a plasma transfusion for aTTP

Answer 62

Plasma transfusions would be less effective for acquired TTP because plasma transfusion would only provide ADAMTS13 enzymes to the blood stream, but would not prevent the destruction of the new enzymes by the antibodies.

Plasmapheresis would replace the entirety of the plasma, including the ADAMTS13 antibodies, which would allow the enzyme to function.

Question 63

Outline the etiology and pathophysiology of Factor V Leiden

Answer 63

Autosomal recessive inheritance

DNA point mutation (Arg –> Gln) Arg506Gln near the polypeptide cleavage site of Factor V
Gln506 is resistant to the cleavage of Activated Protein C –> TF V remains active in common coagulation cascade –> continues to activate prothrombin (TF II) –> increases thrombotic events (hypercoagulation)

Question 64

Pathogenesis of DVT

Answer 64

Hypercoagulability, Endothelial damage, and/or venous stasis can cause DVT

Question 65

Identify the significance of D-dimer levels in thrombotic disorders

Answer 65

D-dimers are fibrin degradation products released when plasmin cleaves cross-linked fibrin

Elevated D-dimers indicate elevated clotting

Question 66

Justify the use of long-term anticoagulation therapy in patients with Factor V Leiden and explain the MOA

Answer 66

Warfarin is a long term anticoagulant

Because Warfarin inhibits Vitamin K, the zymogens produced by the liver are inactivated, including protein C. Protein C is used to promote anticoagulation. So because Warfarin takes a few days to work, it should be paired with a bridging anticoagulant such as Heparin, as it works on the coagulation cascade immediately. Otherwise it can cause hypercoagulability.

Question 67

Outline the Ottawa Ankle Rules

Answer 67

1. Inability to bear weight for more than 4 steps
2. Bone tenderness on posterior lateral malleolus
3. Bony tenderness on posterior medial malleolus
4. Tenderness at base of 5th metatarsal
5. Pain at navicular bone

Question 68

Outline the pathway that causes NSAIDs to delay wound healing

Answer 68

NSAIDS inhibit enzyme cyclooxygenase (COX)

COX converts arachidonic acid –> thromboxanes (TXA), prostaglandins, and prostacyclins

Inhibited COX –> decreased platelet aggregation

Question 69

Identify the role of neutrophils in bacterial infections

Answer 69

Production of ROS
Chemotaxis of other inflammatory cells

Question 70

How does infection cause a fever?

Answer 70

Exogenous pyrogens (bacteria) initiate fever by interacting with macrophages or monocytes –> induces cytokine induction –> cytokines (IL-1 mostly) act on hypothalamus –> synthesis of prostaglandins –> increase of core temperature

Question 71

Staphylococcus aureus

Structure, epidemiology, virulence factor and mode of transmission

Answer 71

Structure: Cocci - round, found in clusters, Gram (+), catalase +

Epidemiology: anywhere dirty (gym, hospitals, skin)

Virulence factor: Protein A - binds to Fc section of IgG antibody to inhibit phagocytosis

Opportunistic MOT - ingestion, direct, transdermal

Question 72

Streptococcus pyogenes

Structure, epidemiology, physiology and mode of transmission

Answer 72

Structure: Cocci - round, found in chains, Gram (+), catalase -

Epidemiology: anywhere dirty (gym, hospitals, skin)

Virulence factor: Toxins (exotoxins result in release of IL-1, IFN-y, TNF-a), enzymes (DNase - destroys neutrophils), protein M (prevents opsonization)

Opportunistic MOT - ingestion, direct, transdermal

Question 73

What test differentiates Staph from Strep

Answer 73

Catalase - staphylococcus has the ability to produce catalase

Question 74

Pathogenesis of Ewing Sarcoma family of tumors

Answer 74

Translocation of EWSR1 gene on C22

t(11;22)(q24;q12) leads to full expression of fusion protein EWS-FLI1 –> increased cell proliferation

Question 75

Describe how the Ewing Sarcoma family of tumors is a systemic disease process

Answer 75

There are four different tumor types affecting different aspects of the body

Ewings Sarcoma - bone
Extraosseous ES - soft tissue
Primitive neuroectodermal tumor - brain
Askin’s tumor - chest wall

Question 76

Explain the significance of LDH levels in Ewing Sarcoma

Answer 76

Ewing sarcoma has rapidly dividing tumor cells, which use aerobic glycolysis of lactate in the presence of oxygen

Increased LDH is indicative of significantly increased cell proliferation