Block 11 - L17-

Question 1

What is the inheritance pattern of NFI?

Answer 1

AD

Question 2

How is NFI diagnosed?

Answer 2

2 of the following:

1. Family history of NF1
2. > 6 cafe’ au lait spots
3. 2+ neurofibromas (soft, fleshy growths)
4. Lisch nodules
5. Optic gliomas
6. Angiofibromas
7. Axillary and/or inguinal freckling

Question 3

How do neurofibromas appear on H&E?

Answer 3

Spindle-shaped cells with collagen and nerves

Question 4

What is the most common CNS tumor?

Answer 4

Optic glioma

Question 5

What are the sequelae of optic glioma (in 1/3 of patients)?

Answer 5

Decreased visual acuity
Proptosis
Strabismus
Headaches
Nausea

Question 6

What are Lisch nodules?

Answer 6

Iris hamartomas, usually seen on slit lamp exam

Question 7

What is a rare orthopedic sign of NF?

Answer 7

Osseous defect of the fibula (one of the first signs in infancy, but rare)

Question 8

___ is common in patients with NF1.

Answer 8

Hypertension (can develop at any age, most cases are essential)

Question 9

How is NF1 managed?

Answer 9

1. Yearly ophthalmologic exams (monitor for optic glioma)
2. Close BP monitoring
3. Removal of NF if they are in areas causing irritation or for cosmetic reasons

Question 10

What are the systemic features of Marfan syndrome (assign point values)?

Answer 10

1. Chest wall deformities - pectus excavatum (1) and pectus carinatum (2)
2. Spontaneous Pneumothorax
3. Scoliosis (greater than 20 degrees) (2)
4. Pes planus (1)
5. Steinberg thumb sign and wrist sign (3)
6. Either Steinberg thumb sign OR wrist sign (1)
7. Lower body segment is greater than the upper body segment (1)
8. Wing span is greater than the height (1)
9. Striae (1)
10. Myopia (1)
11. Mitral valve prolapse (1)

Question 11

What are the ophthalmologic features of Marfan syndrome?

Answer 11

1. Ectopia lentis (upward)
2. Myopia
3. Flat cornea
4. Elongated globe

Question 12

What are the cardiovascular features of Marfan syndrome?

Answer 12

1. Dilation of the ascending aorta (Z score >2)
2. Aortic dissection
3. MV prolapse

Question 13

What is the inheritance pattern of Marfan syndrome?

Answer 13

AD

Question 14

Marfan syndrome is caused by an abnormality in ___, due to a mutation in ___ gene.

Answer 14

Fibrillin (connective tissue); FBN1

Question 15

How is Marfan syndrome diagnosed without a family history?

Answer 15

1. Ao (Z>2) + ectopis lentis
2. Ao (Z>2) + FBN1
3. Ao (Z>2) + systemic features (7+ points)
4. Ectopia lentis + FBN1

Question 16

How is Marfan syndrome diagnosed with a family history?

Answer 16

Family history plus one of the following:

1. Ectopic lentis
2. Systemic features (7+ points)
3. Ao (Z>2 over age 20 and >3 below 20)
4. FBN1

Question 17

Patients with Marfan Syndrome have a ___% risk of passing it onto their children.

Answer 17

50

Question 18

How is Marfan syndrome managed?

Answer 18

1. Annual eye exam
2. Close cardiology follow-up
3. Medications to lower BP (Beta-blockers + Losartan)
4. Limitation of sports participation if aortic root is enlarged
5. Avoidance of weight lifting and scuba diving

Question 19

What is the inheritance pattern of Duchenne’s Muscular Dystrophy (DMD)?

Answer 19

X-linked recessive

Question 20

What are the clinical features of DMD?

Answer 20

1. Progressive muscle weakness
2. Calf hypertrophy
3. Toe walking
4. Lordosis
5. Gower sign

Question 21

What is often the cause of death in patients with DMD?

Answer 21

Heart failure (dilated cardiomyopathy)

Question 22

What protein is mutated in DMD?

Answer 22

Dystrophin (protein that connects the actin of a muscle fiber to the surround ECM)

Question 23

What is the largest known human gene? Where is it located?

Answer 23

Dystrophin gene (DMD); short arm of X chromosome (Xp22.1)

Question 24

Discuss the pathophysiology of DMD caused by mutated dystrophin.

Answer 24

When the membrane does not have structural support of the cytoskeleton, surface membrane rips occur in the cell membrane. CK migrates from the inside of the cell to the outside. Ca2+ migrates into the cell; when combined with proteases, Ca2+ is actiavted and breaks down muscle cells

Question 25

Compare DMD and Becker Muscular dystrophy.

Answer 25

DMD - either deletion of a significant portion of the gene or a missense mutation (no dystrophin protein produced)
BMD - decreased protein, milder phenotype

Question 26

How is DMD managed?

Answer 26

1. Physical therapy
2. Steroid injections in the muscle
3. Cardiac medications to improve function
4. Exon skipping therapy in the future?

Question 27

Approximately 80% of patients with DMD have involvement in exon ___.

Answer 27

51

Question 28

Describe the concept of exon skipping.

Answer 28

Skip reading of mutated exons (which normally cause translation to stop) to restore the reading frame - leads to a functional (albeit shorter) protein

Question 29

What are the symptoms of Beckwith-Wiedemann Syndrome (BWS)?

Answer 29

1. Increased birth weight
2. Neonatal hypoglycemia
3. Hypocalcemia
4. Anterior ear creases
5. Macroglossia
6. Wilms tumor (increased risk)
7. Hepatoblastoma (increased risk)
8. Omphalocele
9. Organomegaly
10. Hemihyperplasia

Question 30

What is the most common cause of BWS?

Answer 30

Duplication of the insulin growth factor receptor (11p)

Question 31

There is an increased incidence of BWS in infants conceived by ___.

Answer 31

IVF

Question 32

What are the symptoms of FAS?

Answer 32

1. Prenatal alcohol exposure
2. Microcephaly
3. Low birth weight
4. FTT
5. Long smooth philtrum
6. Thin upper lip
7. Hearing loss
8. Congenital heart defects

Question 33

What is fetal alcohol effects (FAE)?

Answer 33

Alcohol use during pregnancy, but not enough features to fulfill diagnosis of FAS

Question 34

What four categories are used to diagnose FAS?

Answer 34

1. Prenatal alcohol exposure
2. Dysmorphic features
3. Growth deficiency
4. Cognitive delays

Question 35

How is gestational exposure to alcohol scored?

Answer 35

1: Confirmed absence of exposure
2: Exposure not confirmed
3: Confirmed exposure, level unknown
4: Confirmed exposure to high levels of alcohol

Question 36

How are dysmorphic features scored?

Answer 36

Short palpebral fissure length (hypertelorism), long philtrum, thin upper lip

1: no features
2: 1/3 features
3: 2/3 features
4: all 3 features

Question 37

How is growth scored?

Answer 37

1: height and weight about the 10th percentile
2: height or weight below the 10th percentile
3: heigh and weight below the 10th percentile
4. height and weight below the 3rd percentile

Question 38

How is CNS scored?

Answer 38

1: no neurologic impairment
2: some evidence of neurologic dysfunction
3: significant neurologic dysfunction
4: structural anomalies of the brain/microcephaly

Question 39

How is FAS diagnosed clinically?

Answer 39

1. 4 for all 4 criteria OR

2. 3 level 4’s and 1 level 3

Question 40

How is FAE diagnosed clinically?

Answer 40

1. 1 criteria at level 4

2. Remaining criteria at level 3 or 2

Question 41

Generally, how does metabolic disease present clinically?

Answer 41

Non-specific problems of lethargy, decreased feeding, vomiting - can progress to seizure/coma

*Similar symptoms can be seen with many etiologies, including congenital heart defects and sepsis

Question 42

What is “newborn crash”?

Answer 42

Usually term infant with a well interval presenting with non-specific poor feeding, vomiting, lethargy progressing to seizures and coma; occasional abnormal urine odor

Question 43

DDx - newborn crash

Answer 43

SEPSIS
Adrenal insufficiency
Congenital heart disease
Amino acid abnormality
Urea cycle abnormality
Organic aciduria (proprionic, methymalonic)
Mitochondrial disorder

Question 44

Define metabolic acidosis.

Answer 44

1. Decreased blood pH (<7.4) caused by accumulation of H+
2. Decreased bicarbonate (HCO3<16)
3. Decreased PaCO2 (compensatory hyperventilation)

Question 45

DDx - metabolic acidosis in a newborn

Answer 45

Diarrhea (loss of bicarbonate), renal tubular acidosis, diabetic ketoacidosis, inborn error of metabolism

Question 46

Anion gap = ?

Normal anion gap = ?

Answer 46

Na - Cl - HCO3 = AG

Normal = 10-15

Question 47

What causes a normal anion gap metabolic acidosis?

Answer 47

Diarrhea, renal tubular acidosis (abnormal losses of bicarbonate)

Question 48

What causes an expanded anion gap metabolic acidosis?

Answer 48

Organic acidopathy, ketoacidosis, lactic acidosis (accumulation of fixed acid)

Question 49

What are the clinical and laboratory features of organic acidurias?

Answer 49

Decompensation in the first 2 weeks of life (though glutaric acidemia can present later), acidosis, elevated AG, elevated lactic acid, hypoglycemia, bone marrow suppression, hyperammonemia (200-600)

Question 50

List the 4 organic acidurias.

Answer 50

1. Methylmalonic
2. Isovaleric
3. Proprionic
4. Glutaric acidemia

Question 51

Enzyme defects can result in the inability to convert one amino acid to another, leading to an ___. Give two examples.

Answer 51

Amino acidemia; PKU, homocystinuria

Question 52

Describe the pathophysiology of phenylketonuria (PKU).

Answer 52

Normally, phenylalanine is converted to tyrosine via the enzyme phenylalanine hydroxylase (PAH). In PKU, the enzyme does not function, leading to shunting of phenylalanine to phenylpyruvate, which is then converted to toxic acids (phenyl lactate, phenylacetate, phenylethylamine, phenylacetyl glutamine).

Question 53

What is the inheritance pattern of PKU?

Answer 53

AR

Question 54

How does PKU present?

Answer 54

Poor weight gain, microcephaly, “mousy” odor, loss of IQ points (acid is toxic to the brain)

Question 55

How is PKU managed?

Answer 55

Diet low in protein (only enough PHE to allow for growth); kuvan - medication which can increase the conversion of phenylalanine to tyrosine

Question 56

Describe the pathophysiology of homocystinuria.

Answer 56

Homocysteine is normally converted to cysteine by cystathionine synthase; when this enzyme is non-functional, homocysteine is converted to homocystINE and excreted in the urine. Elevated homocysteine results in a prothrombic state that increases the risk of blood clots.

Question 57

What is the inheritance pattern of homocystinuria?

Answer 57

AR

Question 58

How does hmocystinuria present?

Answer 58

Marfanoid habitus (long fingers, joint hypermobility, tall stature), cognitive delays, downward lens dislocation (different from Marfan’s)

Question 59

Describe the pathophysiology of maple syrup urine disease.

Answer 59

A nonfunctional enzyme in the BCKD complex fails to catalyze the decarboxylation of the alpha-keto acids of leucine, isoleucine, and valine to their respective branched-chain acyl-CoA; as a result, these amino acids increase.

Question 60

How does maple syrup urine disease present?

Answer 60

1. Baby deteriorates in the first 1-2 weeks of life (lethargy, damage to neurons)
2. NH3 is normal or elevated
3. Lactate is normal
4. Glucose is normal/mild hypoglycemia
5. Maple syrup odor to urine
6. Serum amino acids have an elevation of leucine, isoleucine, valine, and alloisoleucine

Question 61

How is maple syrup urine disease inherited?

Answer 61

AR

Question 62

What causes the sweet smell, lethargy, and brain damage in maple syrup urine disease?

Answer 62

Elevated isoleucine - sweet smell
Elevated leucine - transported to the brain, converted to glutamate and glutamine, which cause lethargy and neuron damage

Question 63

How is maple syrup urine disease managed?

Answer 63

Diet low in protein with limited branch chain amino acids

Question 64

What is the purpose of the urea cycle?

Answer 64

To dispose of nitrogen waste and to syntheisze arginine

Question 65

What is the most common urea cycle disorder?

Answer 65

Ornithine transcarbamylase deficiency

Question 66

List the urea cycle disorders.

Answer 66

1. Ornithine transcarbamylase deficiency (OTC)
2. Citrullinemia
3. Argininosuccinate lyase deficiency
4. Arginase deficiency

Question 67

Why are many patients with urea cycle defects often alkalotic?

Answer 67

Because of the accumulation of NH3

Question 68

Explain the urea cycle, beginning with ammonia’s conversion to carbamoyl phosphate (via carbamoyl phosphate synthetase I).
Note - this is not part of the urea cycle.

Answer 68

1. Carbamoyl phosphate is converted to citrulline via ornithine transcarbamoylase.
2. Citrulline is converted to argininosuccinate via argininosuccinate synthetase.
3. Argininosuccinate is converted to arginine and fumarate via argininosuccinase.
4. Arginine is converted to urea and ornithine via arginase.

Ornithine is transported back to the mitochondria to begin the urea cycle again.

Question 69

What are the clinical features of glutaric acidemia?

Answer 69

1. Megalencephaly
2. Normal development until the first episode
3. Profuse sweating or unexplained fevers, irritability
4. Basal ganglia lesions and subdural hematomas

Question 70

How is glutaric acidemia diagnosed?

Answer 70

1. Elevation of glutaric acid in urine organic acids

2. MRI abnormalities - lesions to the basal ganglia and subdural hematomas

Question 71

What is the pathophysiology of the basal ganglion lesions and subdural hematomas in glutaric acidemia?

Answer 71

Glutaric acid is toxic to the brain, resulting in atrophy and additional fluid around the brain (microcephalic macrocephaly); subdural hematomas result from inflammation of the toxins and tearing of vessels

Question 72

What is the most common cause of subdural hematomas in children?

Answer 72

Abuse

Question 73

What is the inheritance pattern of medium-chain acyl-coenzyme A dehydrogenase deficiency (MCAD)?

Answer 73

Autosomal recessive

Question 74

What are the symptoms of MCAD?

Answer 74

Episodic illness with hypoglycemia usually occurring between 3 months and 2 years of age, usually follows fasting for 12 hours or more, or with intercurrent infectious disease, acute episode often starts with vomiting, lethargy, seizures, can progress to coma rapidly

Can cause SIDS (2-3% are due to this)

Question 75

What is the role of the deficient enzyme in MCAD?

Answer 75

Involved in mitochondrial fatty acid beta-oxidation

Question 76

What lab results are seen in MCAD?

Answer 76

1. Hypoglycemia
2. Urine dip negative for ketones despite fasting state
3. Hyperammonemia
4. High uric acid
5. High CPK
6. Organic acids and acylcarnitine studies show an increased C6-C10 dicarboxylics

Question 77

As a group, fatty acid oxidation disorders occur when fat cannot be converted to energy. Where does this process occur?

Answer 77

Mitochondria

Question 78

What are the steps of beta oxidation?

Answer 78

Acyl-CoA

Question 79

What is the most common disorder of fatty acid oxidation?

Answer 79

MCAD

Question 80

How is MCAD treated?

Answer 80

Carnitine supplementation, low fat diet, prevent fasting state

Question 81

Galactosemia is a metabolic disorder resulting from the inability to utilize ___ as an energy source (to convert it to glucose). One of the most common sources of galactose is ___.

Answer 81

Galactose; lactose

Question 82

Galactosemia usually results from the absence of what enzyme?

Answer 82

GALT (Galactose-1-P-uridyl transferase)

Could also be due to GALK or GALE

Question 83

When galactose cannot be converted to glucose, what happens?

Answer 83

It is converted to galactitol, which is toxic to the liver. It can accumulate in the lens of the eye, resulting in cataracts. Urine will show reducing substances (unmetabolized sugars).

Question 84

What is the inheritance pattern of galactosemia?

Answer 84

AR

Question 85

How does classical galactosemia present?

Answer 85

Jaundice, hepatomegaly, vomiting, feeding intolerance, E. coli sepsis (E. coli loves galactose), cataracts; progress rapidly to hepatic toxicity and death from sepsis or bleeding

Question 86

How is galactosemia treated?

Answer 86

1. Lactose free diet

2. Soy formula during infancy (breast milk has lactose)

Question 87

___ are a group of disorders resulting from the inability to properly break down glycogen.

Answer 87

Glycogen storage diseases

Question 88

Glycogen stores sugars in long ___ with ___.

Answer 88

Chains; branches

Question 89

What are the 4 glycogen storage diseases in the hepatic group?

Answer 89

1. Type I (Von Gierke)
2. Type III (DeBrancher defects)
3. Type IV (Branching Enzyme Defect)
4. Type VI: Liver Phosphorylase

Question 90

What is deficient in Type I (Von Gierke)?

Answer 90

Glucose 6 phosphatase

Question 91

How does Type 1 (Von Gierke) present?

Answer 91

3-4 months old, hepatomegaly, FTT, fat cheeks with thin extremities, hypoglycemia with seizures

Question 92

What are the labs seen in Type I (Von Gierke)?

Answer 92

Hypoglycemia
Lactic acidosis
Hyperuricemia
Hyperlipidemia

Question 93

How is Type I (Von Gierke) treated?

Answer 93

1. Preventing hypoglycemia with continuous feeds or cornstarch
2. Restricting galactose and fructose in diet

Question 94

Discuss the pathophysiology of Type I (Von Gierke).

Answer 94

When blood glucose is low, the body breaks down glycogen. It is converted to Glucose-1-phosphate, and then to G6P, and then to glucose (via G6 phosphatase). When this is deficiency, excess G6P is converted to pyruvate, which leads to lactic acidosis and hyperuricemia.

Question 95

What is deficiency in Type III (Cori)?

Answer 95

Glycogen debranching enzymes

Question 96

What are the symptoms of Type III (Cori) disease?

Answer 96

Hepatomegaly, hypoglycemia, short stature, skeletal myopathy, cardiomyopathy

Question 97

What are the 3 glycogen storage diseases in the muscle group?

Answer 97

1. Type II (Pompe)
2. Type V (McArdle)
3. Type VII (phosphofructokinase deficiency)

Question 98

What is deficient in Type V (McArdle)?

Answer 98

Muscle phosphrylase

Question 99

What is the inheritance pattern of Type V (McArdle)?

Answer 99

AR

Question 100

What are the symptoms of Type V (McArdle)?

Answer 100

Begin in the early 20’s
Exercise induced muscle cramps and exercise intolerance
Burgundy colored urine
CPK elevated and rest + increases significantly with exercise

Question 101

How is Type V (McArdle) diagnosed?

Answer 101

Muscle biopsy identifying glycogen in muscle OR PYGM gene test (100% have mutation)

Question 102

How is Type V (McArdle) treated?

Answer 102

Avoid strenuous exercise, IVF with glucose during rhabdomyolysis

Question 103

What is deficient in Type VII?

Answer 103

Fructose-6-phosphatase

Question 104

How does Type VII present?

Answer 104

Presents in childhood, hemolysis, increased uric acid levels, exercise intolerance much worse after carbohydrate meal, early onset of fatigue and pain with exercise

Question 105

Urine smell - maple syrup

Answer 105

Maple syrup urin disease

Question 106

Urine smell - weaty feet

Answer 106

Isovaleric acidemia

Question 107

Urine smell - rotten cabbage

Answer 107

Tyrosinemia