Ch 8: Vitamins & Trace Elements Flashcards

Question 1

Q

What amount of retinol is equivalent to 24 mcg of beta-carotene from food?

A. 2 mcg
B. 4 mcg
C. 2mcg
D. 1mg

Answer

A

A. 2 mcg

1 mcg of retinol has the Vitamin A activity of 12 mcg beta-carotene. The

Question 2

Q

Which of the following nutrients does NOT engage in conversion of homocysteine to methionine?

A. Choline
B. Vitamin D
C. Vitamin B12
D. Folate

Answer

A

B. Vitamin D

B12/folate are main factors in conversion of homocysteine to methionine

Alternatively, choline may be used for this conversion.

Question 3

Q

The first B vitamin deficiency to manifest in people with alcoholism is usually:

A. Niacin
B. Pantothenic Acid
C. Vitamin B6
D. Thiamin

Answer

A

D. Thiamin

Small amounts of thiamin stored in liver = first to become deficient

in malabsorptive or inadequate intake situations

Question 4

Q

Which of the following trace elements is regulated at the level of absorption but not excretion?

A. Zinc
B. Copper
C. Manganese
D. Iron

Answer

A

D. Iron

The control mechanisms that keep iron levels stable in the body occur at the absorption phase.

It is very difficult to eliminate iron except in conditions of blood loss (e.g., blood donation or menstruation)

Question 5

Q

Estimated Average Requirement (EAR)

Answer

A

Intake that meets estimated nutrient needs of 50% of the individuals in a group

Must be derived from scientific studies

Serves as basis for RDA

Question 6

Q

Recommended Dietary Allowance (RDA)

Answer

A

Intake that meets ENN of almost all (97-98%) individuals in that group

Question 7

Q

Adequate Intake (AI)

Answer

A

Established when evidence is insufficient to develop an RDA

Set at a level assumed to ensure nutritional adequacy

Question 8

Q

Tolerable Upper Intake Level (UL)

Answer

A

The max intake = unlikely to pose risk of adverse health effects in almost all individuals

Question 9

Q

What are the 13 vitamins & 1 dietary component that are considered essential?

Answer

A

B-vitamins (8 total): thiamin, niacin, riboflavin, folate, Vitamin B6, Vitamin B12, biotin, and pantothenic acid)

Vitamin C (ascorbic acid)

Fat soluble: A, D, E, K

Dietary component: choline

Question 10

Q

Fat soluble vitamin absorption

Answer

A

In duodenum: fat soluble vitamins → micelles → absorbed into enterocyte

In enterocyte: repackaged into chylomicrons (distribution to extrahepatic tissues)

Question 11

Q

What are Provitamins?

Answer

A

A substance that may be converted within the body to a vitamin

The term previtamin is a synonym

Question 12

Q

Retinol-binding protein (RBP)

Answer

A

Is synthesized in the liver

Required to transport retinol from liver to target tissues

Highly sensitive to nutrition status

Question 13

Q

What is RBP bound to in plasma?

Answer

A

RBP bound to prealbumin

(aka protein transthyretin, TTR)

Question 14

Q

4 functions of Vitamin A

Answer

A

Vision
Epithelial cell regulation
Wound healing
Bone and cellular health

Question 15

Q

How does Vitamin A impact corticosteroids in wound healing?

Answer

A

Reverses inhibitory effect of corticosteroids on wound healing

Question 16

Q

Vitamin A storage

Answer

A

Main: hepatocyte (liver)

Additional: adipose, kidneys, bone marrow, lung, eyes

Question 17

Q

Vitamin A excretion

Answer

A

Feces & Urine

increased amounts excreted in urine during sepsis

Question 18

Q

Vitamin A deficiency - disease states

Answer

A

Malabsorptive disorders (IBD, bariatric surgery, liver disease)

Pregnancy with low PO intakes

Alcoholism - impacts absorption, liver stores Vit A and processes ETOH

Question 19

Q

Vitamin A deficiency - signs and symptoms:

SKIN

Answer

A

Follicular hyperkeratosis (keratin buildup around the hair follicles → bumps on the skin)
Dry skin, itching, irritation

Question 20

Q

Vitamin A deficiency - signs and symptoms:

EYES

Answer

A

Roughened conjunctiva

Bitot’s spots (rough corneal keratin deposition)

Xerophthalmia (dry eyes)

Night blindness

Keratomalacia (cornea soft/cloudy, preceded by xerophthalmia)

Question 21

Q

Vitamin A deficiency - signs and symptoms:

BONES

Answer

A

Excessive bone deposition (new bone is formed)

Question 22

Q

Vitamin A deficiency - signs and symptoms:

OTHER

Answer

A

Impaired wound healing

Question 23

Q

Vitamin A toxicity - disease states

Answer

A

Renal failure (chronic and acute)

Binding capacity of RBP is exceeded → more Vit A circulating unbound → potential to damage cell membranes

Question 24

Q

Vitamin A toxicity - signs and symptoms:

SKIN

Answer

A

Pruritus (itchy skin)

Question 25

Q

Vitamin A toxicity - signs and symptoms:

HAIR

Answer

A

Alopecia (patchy hair loss)

Question 26

Q

Vitamin A toxicity - signs and symptoms:

EYES

Answer

A

Vision disorders (e.g., blurry vision)

Conjunctivitis

Question 27

Q

Vitamin A toxicity - signs and symptoms:

MOUTH

Answer

A

Cheilitis (inflammation of lips; chapped lips)

Question 28

Q

Vitamin A toxicity - signs and symptoms:

NERVOUS SYSTEM

Answer

A

Ataxia (impaired balance or coordination)

Question 29

Q

Vitamin A toxicity - signs and symptoms:

BONES

Answer

A

Bone loss
Bone pain
Hip fractures

Question 30

Q

Vitamin A toxicity - signs and symptoms:

OTHER

Answer

A

Hyperlipidemia

Renal osteodystrophy
= Metabolic bone disease characterized by bone mineralization deficiency due to electrolyte and endocrine abnormalities

Membrane dryness

Muscle pain

Hepatotoxicity

Birth defects

Question 31

Q

Nutrient deficiency that impacts vitamin a

Answer

A

Protein-energy malnutrition and/or zinc deficiency
- Due to RBP-TTR complex
- May compromise circulating serum Vitamin A levels
- Zinc is a component of retinol-binding protein, a protein necessary for transporting vitamin A in the blood.

Decreased circulating serum retinol levels may reflect impaired RBP synthesis and mobilization 2/2 inflammatory process/disease → does not require correction w/ supplementation

Question 32

Q

Vitamin A -

Medication to nutrient interactions

Answer

A

Through fat malabsorption:
Cholestyramine (bile acid sequestrant)
Lomitapide (lipid-lowering agent)
Octreotide (antidiarrheal)
Orlistat (weight control medication)
Mineral oil (laxative)

Corticosteroids (anti-inflammatories) - can cause decreased serum vitamin A

Question 33

Q

How long should Vitamin A be supplemented in setting of wound healing & corticosteroid use?

Question 34

Q

Dose of PO Vitamin A administration to enhance wound healing w/ concurrent steroid use?

Answer

A

3000-4500 RAE/day

Question 35

Q

Calcidiol

Answer

A

25-hydroxy-D

Major circulating form that has no biological activity

Question 36

Q

Calcitriol

Answer

A

1,25-dihydroxyvitamin D

Active form of Vitamin D

Question 37

Q

Principal function of Vitamin D

Answer

A

To maintain serum calcium and phosphorous levels to support:

Neuromuscular function
Bone calcification
Other cellular processes

Question 38

Q

Vitamin D functions (3)

Answer

A

Calcium homeostasis
Pleiotropic effects of Vitamin D
Nosocomial infection (ex: Cdiff)

Question 39

Q

Vitamin D - absorption

Answer

A

80% dietary Vitamin D intake incorporated into micelle

Primarily in distal small intestine
Duodenum uptake = more rapid

Question 40

Q

Vitamin D - storage

Answer

A

Adipose tissue

Liver s/p conversion to calcidiol

Question 41

Q

Vitamin D - excretion

Answer

A

Bile

Minimal amounts lost in urine

Question 42

Q

Vitamin D - populations at risk for deficiency

Answer

A

Inadequate sun exposure
- People wearing clothing/veils with minimal skin exposure
- People indoors much of the time
- Daily use of sunscreen
- Older adults and NH residents
- Dark-skinned individuals

Exclusively breastfed infants

Extensive skin damage (burns)

Fat-malabsorptive disorders

Renal disease (insufficient renal calcitriol production)

Long-term PN

Question 43

Q

Long term PN and Vitamin D status

Answer

A

One study suggests patients on home PN with high prevalence of Vitamin D deficiency despite PO supplementation

Question 44

Q

Best lab to evaluate Vitamin D status?

Answer

A

Circulating 25-hydroxyvitamin D [25(OH)D]

Question 45

Q

Which is NOT a good lab marker to evaluate Vitamin D status and why?

Answer

A

Calcitriol

Decreased calcidiol → serum calcium/phosphorous levels drop → PTH → renal production of calcitriol

= leaves levels elevated/normal in deficiency state

Question 46

Q

Which lab does ASPEN core curriculum (2016) say is a reasonable assay to evaluate Vitamin D status?

Answer

A

Calcidiol

More clearly defined status with surrogate markers (PTH, calcium)

Question 47

Q

Nutrient to nutrient interactions:
Excess vitamin D

Answer

A

Excess Vitamin D stimulates hepatic oxidation and excretion of Vitamin K

Question 48

Q

Certain medications can impact Vitamin D. What are some generalized effects?

Answer

A

Fat malabsorption
Increased vitamin D metabolism, decreased serum levels
Cause decreased serum levels
Increase drug effects

Question 49

Q

Meds that decrease the absorption of Vitamin D through fat malabsorption

Answer

A

Cholestyramine (bile acid sequestrant)

Lomitapide (lipid-lowering agent)

Octreotide (antidiarrheal)

Orlistat (weight control medication)

Mineral oil (laxative)

Question 50

Q

Meds that increase vitamin D metabolism and decrease its serum levels

Answer

A

Phenobarbital (anticonvulsant)

Phenytoin (antiepileptic)

Valproic acid (antiepileptic)

Rifampin (antibiotic)

Question 51

Q

Meds that may cause decreased serum levels of Vitamin D

Answer

A

Corticosteroids (anti-inflammatories)

Carbamazepine (anti-epileptic)

Isoniazid (antitubercular)

Question 52

Q

Vitamin D may increase the drug effects of this medication:

Answer

A

Digoxin (antiarrhythmatic)

Question 53

Q

Vitamin D deficiency - signs and symptoms:

BONES

Answer

A

Osteomalacia (softening of the bones; ratio of bone mineral to bone matrix is low)

Question 54

Q

Vitamin D deficiency - signs and symptoms:

NERVOUS SYSTEM

Answer

A

Tetany (involuntary muscle contractions and overly stimulated peripheral nerves)

Caused by electrolyte imbalances — most often low blood calcium levels

Question 55

Q

Vitamin D deficiency - signs and symptoms:

OTHER

Answer

A

Hypocalcemia

Question 56

Q

Vitamin D toxicity - signs and symptoms:

BONES

Answer

A

Calcification of soft tissues (cardiovasculature, lungs)

Bone pain

Question 57

Q

Vitamin D toxicity - signs and symptoms:

NERVOUS SYSTEM

Answer

A

Confusion
Psychosis
Tremor

Question 58

Q

Vitamin D toxicity - signs and symptoms:

OTHER

Answer

A

Hypercalcemia
Can cause N/V, weakness, and frequent urination

Hypercalciuria
→ kidney problems (formation of calcium stones)

Question 59

Q

Causes of Vitamin D toxicity

Answer

A

Large doses of vitamin D supplements

Question 60

Q

Supplementation Rx for Vitamin D deficiency

Answer

A

50,000 IU 1x/week x8 weeks →
1000 IU/d for several months

Question 61

Q

Vitamin E - What is ɑ-tocopherol?

Answer

A

Most active and naturally occurring form of Vitamin E

Antioxidant activity, inhibits cell proliferation, platelet aggregation, monocyte adhesion

Question 62

Q

Vitamin E - What is 𝝲-tocopherol?

Answer

A

Predominant form of Vitamin E in American diet

Anti-inflammatory, anti-neoplastic, and natriuretic properties

Question 63

Q

What is Vitamin E’s primary function?

Answer

A

Antioxidant activity

Principal function is maintenance of membrane integrity in body cells via antioxidant activity

Inhibits lipid peroxidation → protects integrity of all biological membranes

Antioxidant activity: trapping peroxyl free radicals in cell membranes to protect against oxidation

Sufficient Vitamin E is critical in oxidative stress states (chronic inflammation, sepsis, SIRS, organ failure)

Question 64

Q

Where is Vitamin E absorbed?

Answer

A

Jejunum

Non-saturable passive diffusion with percentage absorbed decreasing with increases of PO intake

Answer 64

A

Adipose tissue, muscle, liver

Answer 65

A

Primarily: urine and bile

Significant amounts found in feces d/t body’s limited absorption of Vitamin E

Answer 66

A

Fat malabsorptive disorders
- Prolonged steatorrhea
- Crohn’s disease
- Cystic fibrosis

Compromised biliary function

Resection of ileum or small intestine

Long-term PN without Vitamin E supplementation

Answer 67

A

Ceroid pigmentation (age spots)

Answer 68

A

Vision changes

Deficiency weakens light receptors in the retina and other cells in the eye. This can lead to loss of vision over time

Answer 69

A

Ophthalmoplegia (paralysis of muscle that controls eye movement)

Ptosis (drooping upper eyelid)

Vision loss

Dysarthria (weakness in muscles used for speech → slurred speech)
* Can’t control tongue or voicebox

Ataxia (impaired balance or coordination)

Neuronal degeneration

Answer 70

A

Vitamin E deficiency

Answer 71

A

Bruising from decreased Vitamin K absorption

Answer 72

A

Inclusion bodies in bone marrow

Answer 73

A

Thrombocytopenia (low platelet level)
→ bleeding into the tissues, bruising, and slow blood clotting after injury

Cerebral hemorrhage

Impaired neutrophil function

Abrogated granulocytopenic response to antigen

Impaired coagulation

Answer 74

A

Prolonged depletion of Vitamin E

Answer 75

A

Plasma or serum Vitamin E (ɑ-tocopherol)

Answer 76

A

A risk for Vitamin E deficiency

Answer 77

A

Intakes >1200 mg/d Vit E interferes with Vitamin K absorption and metabolism

May be problematic for patients on Warfarin

800-1200 mg/d Vitamin E may decrease platelet adhesion

Answer 78

A

Through fat malabsorption:
Cholestyramine (bile acid sequestrant)
Lomitapide (lipid-lowering agent)
Octreotide (antidiarrheal)
Orlistat (weight control medication)
Mineral oil (laxative)

Answer 79

A

Cyclosporine (immunosuppressant)

Answer 80

A

Patients with a coagulation defect

Answer 81

A

Clotting
Bone Health

Answer 82

A

Clotting is measured in terms of Prothrombin Time (PT)

Variance in measurement → use of international normalized ratio (INR)

Answer 83

A

High INR: blood clots slower than desired

Low INR: blood clots faster than desired

Answer 84

A

Warfarin increases INR

Answer 85

A

Vitamin K decreases INR

Answer 86

A

Fat malabsorption
IBD
Antibiotic therapy
Long-term PN without ILE
NPO status

Answer 87

A

Bruising
Prolonged bleeding

Answer 88

A

Decreased bone density

Answer 89

A

Increased prothrombin time

Answer 90

A

Severely compromised liver function

Answer 91

A

fatal anemia
hyperbilirubinemia
severe jaundice
anaphylactoid reaction

Answer 92

A

Plasma phylloquinone - major circulating form

More sensitive indicator of Vit K status

Answer 93

A

Excess Vitamin A or Vitamin E → decrease absorption of Vitamin K

Excess serum/plasma Vitamin D stimulate hepatic oxidation → excretion of Vitamin K

Answer 94

A

Cholestyramine (bile acid sequestrant)
Lomitapide (lipid-lowering agent)
Octreotide (antidiarrheal)
Orlistat (weight control medication)
Mineral oil (laxative)

Answer 95

A

Phenobarbital (sedative)
Phenytoin (antiepileptic)

Answer 96

A

Negates its effects

Answer 97

A

Guidelines for Vitamin K deficiency do not exist

PO or IVPB: 2.5 to 10mg 2x/week to daily is common

Answer 98

A

Warfarin + continuous TFs → decreased Warfarin absorption

Evidence supports that Warfarin irreversibly binds with plastic tubing

Answer 99

A

Parenteral MVI infusions

Lipid emulsions (ILEs) - amount varies between manufacturers

Propofol administration (1.7 mcg Vitamin K per mL)

Answer 100

A

Antioxidant
* Reacts directly with superoxide, hydroxyl radicals, and singlet oxygen

Reducing equivalents and cofactor for reactions requiring reduced metals

Many complex, functional roles
- Collagen synthesis
- Carnitine
- Neurotransmitters
- Enhancement of intestinal absorption of nonheme iron
- Cholesterol hydroxylation → bile acids
- Reduction of toxic transition metals
- Reductive protection of folic acid and Vitamin E
- Immune-mediated and antibacterial functions of WBC

Answer 101

A

Ileum - primary

Some absorption in jejunum via sodium/energy-dependent active transport

SATURABLE AND DOSE DEPENDENT

Answer 102

A

Sodium/energy-dependent active transport

Answer 103

A

Vitamin C is not stored in the body

Answer 104

A

Urine

When serum ascorbic acid levels reach 90 mcmol/L, renal clearance sharply increases

Answer 105

A

Studies show intake <10mg/d causes frank signs of scurvy within 30 days

Answer 106

A

Increases absorption of iron (reduced Fe3+ to Fe2+)

Absorptive benefit plateaus at 75mg Vit C

Same mechanism is believed to increase oxidative stress if Vit C taken in excess because Fe2+ can react with hydrogen peroxide → deleterious hydroxyl radical

Answer 107

A

> 3g/d Vit C decreased acetaminophen excretion by 75% (per one study)

Answer 108

A

Tetracycline (antibiotic)
Aspirin
Corticosteroids

Answer 109

A

Allopurinol (xanthine oxidase inhibitor AKA uric acid reducer)

Answer 110

A

Older adults

Malabsorptive disorders

Poor diets combined with ETOH

DM2 and certain cancers can increase Vitamin C turnover

Tobacco increased need → tobacco use increases free radical production

Answer 111

A

Capillary rupture

Delayed wound healing

Petechiae

Tiny round brown-purple spots due to bleeding under the skin

Perifollicular hemorrhage

Hyperkeratotic papules

Pruritic, dry, scaling, hyperpigmented, and thickening plaques and papules that are skin-colored or erythematous

Answer 112

A

Corkscrew hairs

Answer 113

A

Bleeding gums (from weakened collagen)

Answer 114

A

Joint effusions

Answer 115

A

Hypochondriasis
* Obsession with the idea of having a serious but undiagnosed medical condition

Increased susceptibility to infection

Answer 116

A

N/V/D
Kidney stones

Answer 117

A

Renal failure
Kidney stones
Iron overload disease
Heparin/warfarin therapy

Answer 118

A

100 mg TID (PO)

or can give an initial dose of 60-100 mg IV

Answer 119

A

100-200 mg/day

Answer 120

A

frequent reports of ascorbate deficiency

Reports indicate Vitamin C status deteriorates during hospitalization and from medical/surgical stress → poor wound healing

Answer 121

A

Hyperglycemia: prevents Vitamin C transport

Needed for normal leukocyte function

Can alter glucometer blood glucose measurements

Answer 122

A

Competes with uric acid reabsorption in the kidneys (gout)

Increases oxalate formation and absorption → more pronounced in renal failure

Answer 123

A

Energy transformation (CHO, BCAA)

Synthesis of pentoses and reduced NADPH (nicotinamide adenine dinucleotide phosphate)

Membrane nerve conduction, muscle contraction

Answer 124

A

Magnesium

Adenosine triphosphate (ATP)

The enzyme, thiamin pyrophosphokinase

Answer 125

A

Energy transformation

Synthesis of pentoses and reduced NADPH (nicotinamide adenine dinucleotide phosphate)

Membrane nerve conduction / muscle contraction
* TTP - structural component of nerve membranes, can also function in nerve conduction

Answer 126

A

Metabolism of carbohydrates, branched-chain amino acids, and fatty acids

Answer 127

A

Proximal small intestine – especially the jejunum

Answer 128

A

Both an active or passive diffusion

Dependent on intestinal thiamin concentration
Saturable, energy-dependent active transport at low physiological levels
Passive during high intake

Answer 129

A

30mg stored in the body as TPP or TMP

Most found in skeletal muscle (50%)

Answer 130

A

ETOH use → impaired thiamin absorption

Long term PN or dialysis

Refeeding syndrome or malabsorption

Hyperemesis gravidarum and patients with protracted vomiting

Gastric surgery

Increased demand with marginal nutrition status

Answer 131

A

Nystagmus

Involuntary rhythmic side-to-side, up and down or circular motion of the eyes

Answer 132

A

Dry beriberi
* Paresthesia (pins and needles)
* Weakness in lower extremities

Wernicke-korsakoff syndrome & Wernicke encephalopathy
* Mental status changes
* Global confusion
* Nystagmus
– Involuntary rhythmic side-to-side, up and down or circular motion of the eyes
* Polyneuritis
–Inflammation of several peripheral nerves at the same time
* Gait ataxia (abnormal, uncoordinated movements)
* Stupor

Answer 133

A

Wet beriberi:
High-output cardiac failure
Dyspnea
Hepatomegaly
Tachycardia
Oliguria
Sodium and water retention
Elevated lactic acid

Bariatric beriberi: acute post-gastric reduction surgery
* More prevalent since increase in bariatric surgery

Answer 134

A

Central nervous system

Answer 135

A

It can cause neuropathy but NOT anemia

Answer 136

A

Beriberi is characterized by muscle weakness in BLE with impaired nerve conduction 2/2 inadequate thiamin intake with adequate CHO intake

Answer 137

A

Absence of thiamin →
inhibition of pyruvate dehydrogenase →
CHO metabolism driven toward lactic acid fermentation →
build up of lactic acid

When left untreated → fatal lactic acidosis

Answer 138

A

Magnesium

Necessary for conversion of thiamin → active form (TPP)
* Deficiency renders thiamin unusable

Answer 139

A

Causes deficiency 2/2 diuretic effect → increased urinary thiamin excretion

Answer 140

A

Theophylline

Answer 141

A

Synthesized in the liver → cirrhosis can contribute to deficiency

Answer 142

A

Precursor to 2 major enzyme derivatives involved in enzymatic reactions and intermediary metabolism

FMN (flavin mononucleotide)

FAD (flavin adenine dinucleotide)

Answer 143

A

Serves as a component of FMN and FAD as an electron transport intermediary for oxidation-reduction reactions

Answer 144

A

Antioxidant activity

Coenzyme FAD is required for glutathione reductase which protects against lipid peroxidases
FAD is involved in micronutrient metabolism
Receives electrons from fatty acid oxidation and Krebs cycle intermediates → donates to ETC for production of ATP

Answer 145

A

Conversion of Vitamin B6 to its active form
Synthesis of active form of folate
Catabolism of choline

Answer 146

A

Dissociates from the coenzyme derivatives in the stomach via HCl (hydrochloric acid)

Answer 147

A

Proximal portion of the small bowel

via a saturable, sodium-dependent carrier mechanism

Answer 148

A

Presence of food (likely from delaying intestinal transit)

Bile salts

Answer 149

A

Copper, zinc, iron, manganese → form chelates with riboflavin → prevent abs

ETOH can impair digestion and absorption

Answer 150

A

Most riboflavin is used immediately and not stored in the body

Answer 151

A

Alcoholism 2/2 decreased intake and absorption

Thyroid disorders 2/2 altered riboflavin metabolism

DM2, trauma, extreme stress → excrete more riboflavin than normal

Chronic malabsorptive disorders

Critically ill patients

Answer 152

A

Seborrheic dermatitis of face or scrotum

Answer 153

A

Visual impairment
Corneal vascularization
Photophobia

Answer 154

A

Cheilosis/Angular stomatitis
* Cracking, crusting, and scaling of the corners of the mouth

Glossitis
* Swollen and inflamed; makes the surface of the tongue appear smooth

Edema

Hyperemia of oral/pharyngeal mucosa

Sore throat

Answer 155

A

Peripheral nerve dysfunction

Answer 156

A

Normochromic normocytic anemia

riboflavin deficiency can lead to anemia because it alters iron absorption

Answer 157

A

Toxicity from food and supplements is rare

Answer 158

A

Tricyclic antidepressants
Tetracycline (antibiotic)

Answer 159

A

NAD can be synthesized from tryptophan

Requires riboflavin (as FAD or FMN)

Answer 160

A

60 mg tryptophan

Answer 161

A

NAD/NADP: hydrogen donors or electron acceptors
* Participates in metabolism of amino acids, fatty acids, CHO
* Donates to electron transport chain to produce ATP

Repair DNA

Calcium mobilization

NADPH: helps regenerate body’s antioxidant systems
* Reduces dehydroascorbate (oxidized vitamin C) and glutathione

Treatment for hyperlipidemia

Answer 162

A

Rapid absorption from stomach and intestine by active transport (low concentrations) and passive diffusion (high concentrations)

NAD & NADP → enzymatically hydrolyzed in intestinal mucosa → release nicotinamide (major form in the blood)

Answer 163

A

Urine

Amount excreted r/t form of niacin ingested and niacin status of individual

Little nicotinamide and nicotinic acid is excreted → actively reabsorbed by glomerular filtrate
Methylnicotinamide (methylated in the liver) is primary urinary metabolite

Answer 164

A

Pellagra: can affect the GI tract, skin and nervous system

Four D’s -
dermatitis, diarrhea, dementia, death

Answer 165

A

Malabsorptive disorders

Alcoholism

Older adults

Patients on antitubercular medication (isoniazid or mercaptopurine)

Answer 166

A

Dermatitis

Sun sensitivity causing symmetrical pigmented rash

Answer 167

A

Glossitis
* Swollen and inflamed; makes the surface of the tongue appear smooth

Answer 168

A

Dementia
Apathy
Fatigue
Memory loss
Peripheral neuritis
Extremity paralysis

Answer 169

A

Diarrhea
Vomiting

Answer 170

A

Longterm use of high dose supplementation

Answer 171

A

Flushing
Heat
Vasodilation
Itching

Answer 172

A

GI irritation
Severe hepatitis
Glucose intolerance (DM)
Myopathy

Answer 173

A

No interactions identified

Answer 174

A

Isoniazid (tuberculosis treatment) → decrease niacin levels by inhibiting production from tryptophan

Mercaptopurine (cancer/autoimmune treatment) → interferes with conversion of niacin to NAD

Answer 175

A

Isoniazid (tuberculosis treatment) → decrease niacin levels by inhibiting production from tryptophan

Answer 176

A

Mercaptopurine (cancer/autoimmune treatment) → interferes with conversion of niacin to NAD

Answer 177

A

Coenzyme forms participate in 100+ enzymatic reactions:
* Protein, AA, lipid metabolism
* Gluconeogenesis
* CNS development
* Neurotransmitter synthesis
* Heme biosynthesis
* Normal immune function

PLP and PMP – interconversion of AA, facilitating transamination and deamination reactions

Pathway for decreasing homocysteine levels → conversion to cysteine

Answer 178

A

Jejunum

Ingested phosphorylated forms → hydrolysis to remove phosphate group

Uptake by intestinal epithelial cells → via carrier-mediated, pH-dependent mechanism prior to entry into the portal vein

Absorption: 71-82%

Liver hepatocyte converts → PLP (metabolically active form)

Answer 179

A

60-90% of Vitamin B6 in the plasma = PLP → most bound to albumin for transport

Answer 180

A

Albumin for transport

Answer 181

A

Muscle contains the most PLP (75-80%)

Answer 182

A

Alcoholism

Renal patients maintained on dialysis

Older adults

Medication therapies that inhibit vitamin activity (see drug-nutrient interaction)

Answer 183

A

Seborrheic dermatitis

Answer 184

A

Angular stomatitis
Cheilosis
Glossitis

Answer 185

A

Vitamin B6

Answer 186

A

Microcytic anemia

Answer 187

A

High food intake of B6 and large oral supplementation (>500mg/d)

100mg/d have been associated with Lhermitte’s sign
* An electric shock-like sensation that occurs on flexion of the neck
* Suggestive of an effect on the spinal cord

50mg more than the UL (100mg) in patients undergoing intestinal transplant → accumulation of PLP in RBC 30x the upper limit of normal

> 2000mg have impaired motor control and paresthesia (pins & needles)

Answer 188

A

Dermatologic lesions

Answer 189

A

Sensory neuropathy

Ataxia

Areflexia (the absence of deep tendon reflexes)

Impaired cutaneous and deep sensations

Answer 190

A

B6 is needed for interconversion of one amino acid to another

Deficiency can lead to alterations in amino acid pool

Answer 191

A

Isoniazid (tuberculosis medication)
Oral contraceptives
Corticosteroids (anti-inflammatories)
Penicillamine (chelating agent)

Answer 192

A

Naturally occurring in foods of animal origin → provide B12 in the following coenzyme forms:

Methylcobalamin - biologically active form
Hydroxylcobalamin
Deoxyadenosylcobalamin - biologically active form

Answer 193

A

Cyanocobalamin

Answer 194

A

1) Needed for conversion of homocysteine to methionine (benign amino acid)

2) Conversion of methylmalonyl coenzyme A (CoA) → succinyl-CoA
* For degradation of certain amino acids and odd chain fatty acids

Answer 195

A

Increased risk of CVD, stroke, dementia, Alzheimer’s disease, and osteoporosis

Answer 196

A

When deficient in B12, folate becomes “trapped” in its methyl (inactive) form

1) Homocysteine (+MS) → methionine
2) Simultaneous: demethylation of 5-methyltetrahydrofolate → THF

Methylcobalamin is a cofactor for methionine synthetase (MS, enzyme that converts homocysteine to methionine)

Answer 197

A

Methyl-folate trap where folate is “trapped” in its inactive form

Answer 198

A

HCl and pepsin (from gastric secretions) release B12 from proteins

→ haptocorrin + free B12 → small intestine

Haptocorrin: glycoprotein secreted by salivary glands, swallowed with food

Answer 199

A

Pancreatic proteases hydrolyze haptocorrin and free B12 is released

Answer 200

A

free B12 + IF = IF-B12 complex → ileum

Intrinsic factor: glycoprotein produced by gastric parietal cells

Answer 201

A

IF-B12 complex binds to cubilin for absorption → enterocyte

Cubilin: specific IF receptor on GI epithelial cells

Answer 202

A

3-4 hours after intestinal absorption: transferred to transcobalamin II (transport protein) → portal circulation

Taken up by liver first, then bone marrow and erythrocytes

Normal gastric function: 50% dietary B12 absorbed

B12 is secreted into bile and most is reabsorbed via enterohepatic circulation

Answer 203

A

Liver

Unlike other water soluble vitamins

Answer 204

A

Pancreatic insufficiency
* Interfere with release of free B12 from haptocorrin → prevent attachment to IF

Impaired HCl production/low secretion
* Older adults
* Patients with H.pylori infections
* Histamine-2 (H2) antagonists and proton pump inhibitors (PPI)

All or part of ileum or stomach removed

Chronic malabsorption

Vegetarian and vegan populations

Metformin use
* Lowers absorption, mechanism unknown

Answer 205

A

Neurologic → hematologic and GI abnormalities

Answer 206

A

Malabsorption syndromes

Gastrectomy
Gastric bypass
Ileal resection
Crohn’s dz

Answer 207

A

Bone marrow changes
Bone fractures

Answer 208

A

Glossitis

Answer 209

A

Diminution of vibration and/or position sense
Paresthesia (pins & needles) of hand/feet
Unsteadiness
Cognitive decline
Confusion
Depression
Mental slowness
Poor memory
Delusions
Overt psychosis

Answer 210

A

Megaloblastic anemia
- Type of anemia characterized by very large red blood cells

Leukopenia
- Low white blood cell count

Thrombocytopenia
- Decreased platelets

CVD

Neutrophil nuclei hypersegmentation

Pancytopenia
- A rare manifestation of vitamin B12 deficiency
- Combination of: anemia, leukopenia, thrombocytopenia

Answer 211

A

No Tolerable Upper Intake Level (UL) has been established for B12, due to its low level of toxicity

Answer 212

A

Excess Vitamin C intake (500mg) in single dose may temporarily impair B12 bioavailability from foods and destroy the vitamin

Answer 213

A

Loosely bound to albumin and folate-binding proteins (AKA folate carriers or folate receptors)

Answer 214

A

AA metabolism and nucleic acid synthesis

Coenzyme in transfer of single carbon fragments from one compound to another

Answer 215

A

Homocysteine

THF donates a methyl group to cobalamin for regeneration of methionine from homocysteine

Pregnancy - DNA synthesis for embryonic development

Neural tube defects (NTDs) = DNA fragility and strand breakage

Answer 216

A

Polyglutamates → monoglutamate in order to be absorbed

Zinc dependent enzymes (conjugases) in jejunal brush border

Answer 217

A

Secreted into bile → recirculate via enterohepatic circulation

Answer 218

A

Minimal due to reabsorption via enterohepatic bile circulation

Answer 219

A

Alcoholism (decreased intake and absorption

Pregnancy - increased demand for DNA synthesis in embryonic development

Periconceptual and premenopausal women

Conditions/diseases that impair bile secretion → limit folate recirculation

Answer 220

A

Cheilosis

Answer 221

A

Nervous instability
Dementia

Answer 222

A

Megaloblastic or macrocytic anemia
Neutrophil hypersegmentation (early indicator of deficiency)
Diarrhea
Weight loss
Depression of cell-mediated immunity
CVD

Answer 223

A

It is extremely rare to reach a toxic level when eating folate from food sources

UL for folic acid is set at 1,000 mcg daily because studies have shown that taking higher amounts can mask a vitamin B12 deficiency

Answer 224

A

Zinc can impair the absorption rate of folate

Answer 225

A

Carbamazepine (antiepileptic)
Estrogen therapy
Oral contraceptives
Phenobarbital (sedative)
Phenytoin (antiepileptic)
Triamterene (diuretic)

Answer 226

A

Cholestyramine (bile acid sequestrant)
Metformin (insulin sensitizer)
Sulfasalazine (anti-inflammatory)
Pancrelipase (pancreatic enzyme)

Pancrelipase may reduce the effectiveness of folic acid and iron by interfering with their absorption.

Answer 227

A

Trimethoprim (antibiotic)

Answer 228

A

Rifampin (antitubercular agent)

Answer 229

A

Seizures in phenytoin therapy

Answer 230

A

Free biotin
Biocytin (protein-bound coenzyme; biotin bound to lysine)

Answer 231

A

Bacteria in the intestine can synthesize biotin

Answer 232

A

Avidin

Glycoprotein in raw egg whites

Binds tightly to dietary biotin and prevents biotin’s absorption in the GI tract

Answer 233

A

Necessary for the genetic expression of >2000 enzymes

Cofactor for 4 carboxylase enzymes

Answer 234

A

Acetyl-CoA carboxylase for FA synthesis
* Leucine catabolism yields acetyl CoA and acetoacetate

Pyruvate carboxylase for gluconeogenesis

Propionyl-CoA carboxylase for propionate metabolism

3-methylcrotonyl-CoA carboxylase for BCAA catabolism

Answer 235

A

Jejunum

Facilitated diffusion

Answer 236

A

Water soluble vitamin; it’s not stored

Answer 237

A

Long term PN

Alcoholism - chronic exposure to alcohol inhibits the absorption of biotin

Partial gastrectomy

Biotinidase deficiency (inherited autosomal recessive trait)

Answer 238

A

Biocytin requires biotinidase (enzyme in small intestine) to cleave lysine from biocytin

Answer 239

A

Pallor
Erythematous seborrheic dermatitis

Answer 240

A

Vision problems

Answer 241

A

Glossitis
Cheilosis

Answer 242

A

Nervous instability
Dementia
Hallucinations
Paresthesia (pins and needles) in extremities
Depression

Answer 243

A

Hypotonia – decreased muscle tone
Anorexia
N/V
Lethargy
Muscle pain
Ketolactic acidosis
Elevated cholesterol

Answer 244

A

No UL has been established because there are no reports of toxicity

Answer 245

A

No nutrient interactions identified

Answer 246

A

Carbamazepine (antiepileptic)

Answer 247

A

Component of CoA

Answer 248

A

As CoA - involved in energy released from fat, CHO, and ketogenic amino acids

Gluconeogenesis

Heme and sterol synthesis

Most acetylation reactions

Synthesis of bile salts, cholesterol, steroid hormones, and fatty acids

Transport of long chain fatty acids → mitochondria for catabolism through beta-oxidation

Answer 249

A

Dietary CoA → pantothenic acid in intestinal lumen

Passive diffusion or saturable, sodium-dependent active transport

Transported by erythrocytes throughout the body

Answer 250

A

CoA, in body tissues

Answer 251

A

Occurs in conjunction with other MN deficiencies or conditions such as:
Diabetes
IBD and alcoholism 2/2 impaired absorption

Ingestion of large amounts of ethanol → may have an increased requirement

Answer 252

A

Poor wound healing

Answer 253

A

Neuromuscular disturbances
Numbness
Parethesias - pins and needles
Staggering gait
Mental depression
Listlessness
Irritability
Restlessness
Malaise
Sleep disturbances

Answer 254

A

Muscle cramps
Fatigue
N/V/D
Abdominal cramps
Hypoglycemia
Increased insulin sensitivity
Compromised immune function
Diminished engraftment

Answer 255

A

Rare. Diarrhea noted to occur in doses >10g/day

Answer 256

A

None identified

Answer 257

A

Tetracycline (antibiotic) – may cause decreased serum pantothenic acid

Answer 258

A

Nearly all dietary choline found in the form of choline phosphatides (lecithin and sphingomyelin)

Betaine (oxidized form) also present in diet, but can’t be directly converted to choline

Answer 259

A

Methionine, folic acid, B12, and betaine

Answer 260

A

Needed for neurotransmitter synthesis (acetylcholine), cell membrane signaling (phospholipids), and lipid transport (lipoproteins)

By-product betaine can act as a B12 substitute for regeneration of methionine from homocysteine

Answer 261

A

Cell membrane integrity

Methyl metabolism

Cholinergic neurotransmission

Transmembrane signaling

Transport and metabolism of lipid cholesterol

Answer 262

A

Small intestine

Uptake via choline transporter proteins → liver via portal vein

Answer 263

A

Liver

When supply is low, choline is recycled in liver and redistributed by kidneys, lungs, and intestines → liver and brain

Answer 264

A

Excess choline → betaine (provides methyl groups for compounds like homocysteine)

Answer 265

A

Very small amounts excreted in urine

Answer 266

A

When demand for choline is high–
* Pregnancy
* Lactation
* Hypermetabolic states

Postmenopausal

De novo synthesis diminishes with diminished estrogen

Long-term PN without choline

Answer 267

A

Impairment of verbal and visual memory

Hepatic steatosis

Answer 268

A

Evidence indicates choline deficiency may contribute to PN-induced liver dysfunction → hepatic steatosis and eventual hepatic failure

Answer 269

A

PN 2/2 SBS who develop a choline deficiency are more susceptible to hepatic issues

Impairment in verbal/visual memory may be r/t insufficient acetylcholine synthesis

Answer 270

A

liver disease

atherosclerosis

cancer

possibly neurologic disorders (NTDs, Alzheimer’s disease, memory problems)

Answer 271

A

Very high PO intakes

Answer 272

A

Excessive salivation

Answer 273

A

Hypotension
Anorexia
Fishy body odor
Hepatotoxicity

Answer 274

A

Betaine can replace B12 to replenish methionine from homocysteine through methyl group donation

Answer 275

A

Interactions between choline and meds have not been identified

Answer 276

A

No parenteral supplements at this time

Dextrose and protein components of PN do not contain choline

Part of lipid emulsions in form of phosphatidylcholine

20% lipid emulsion contains 13.22 mcmol of choline per mL

Answer 277

A

Heme & Nonheme

Answer 278

A

Heme - derived from hemoglobin and myoglobin molecules found in animal flesh

Nonheme - plant derived

Answer 279

A

Heme is more efficiently absorbed

Answer 280

A

Presence of organic compounds that increase acidity:

Vitamin C
HCl
Lactic acid
Acidic amino acids aspartic and glutamic acids

Answer 281

A

Ferrous (Fe2+) = better absorbed
* Acidic compounds help maintain nonheme iron in this form
* Animal heme is in this form

Ferric (Fe3+)

Answer 282

A

Duodenum and jejunum

Answer 283

A

Heme iron → globin fraction removed → absorbed intact into enterocyte

In intestinal cell: hydrolyzed to ferrous iron

Answer 284

A

Nonheme iron → released from food in the stomach in ferric form (Fe3+) → converted to ferrous iron via gastric acid

Binds to receptors in intestinal cell (glycocalyx and brush border)

Answer 285

A

Transferrin
* Regulates the absorption of iron into the blood

Ferroportin
* Controls export of iron from cells to blood
* Regulated by the hormone hepcidin

Answer 286

A

Ferritin
* Short term iron storage – found in cells and plasma
* Soluble iron; readily available to body when needed

Hemosiderin
* Long-term iron storage site – found only in cells
* Insoluble form; not readily available to body

Answer 287

A

Hemoglobin - oxygen transport

Myoglobin - muscle iron storage

DNA synthesis

Electron transport – oxidative production of cellular energy (ATP)

Answer 288

A

Suppresses iron transport (upregulation of hepcidin production)

Serum iron depressed

Serum ferritin increased

Answer 289

A

Reduces availability of iron for iron-dependent microorganism proliferation

May also reduce free radical production and oxidative damage to membranes and DNA

Answer 290

A

Tightly regulated, most iron is conserved and recycled

Primarily excreted via Feces

Answer 291

A

Women of childbearing age

Patients hospitalized with excess blood sampling or loss

Decreased gastric acid production
* Older adults (gastric acid production decreases with age)

Concomitant use of meds that reduce stomach acidity → impair iron absorption
* Antacids
* H2 antagonists
* PPIs

Malabsorptive states → ineffective absorption
* Celiac disease
* Crohn’s disease
* Pernicious anemia
* Achlorhydria (stomach does not produce HCl, part of gastric acid)

Reduced absorption
* Roux-en-Y GBP or other GI surgery
* Injury
* Inflammation

Answer 292

A

SKIN - Pallor

NAILS - Koilonychia (spoon nails; soft nails that look scooped out)

EYES - Conjunctival pallor

MOUTH - Glossitis

NERVOUS SYSTEM
Impaired behavioral and intellectual performance

Answer 293

A

Microcytic, hypochromic anemia
Tachycardia
Poor capillary refilling
Fatigue
Sleepiness
Headache
Anorexia
Nausea
Reduced work performance
Impaired ability to maintain body temperature in cold environments
Decreased resistance to infections
Increased lead absorption
Adverse outcomes during pregnancy

Answer 294

A

Exposure to iron that exceeds body’s physiological protection mechanisms

Hemochromatosis (genetic disorder) → increases amount of iron absorbed from diet

Answer 295

A

SKIN
Skin pigmentation

OTHER
Organ damage (e.g., liver cirrhosis, heart enlargement, pancreatic damage)

Answer 296

A

Phytic acid - grain fibers

Oxalic acid - spinach, chard, tea, chocolate

Polyphenols - coffee, tea, cocoa

Other nutrients - calcium, zinc, manganese

Answer 297

A

In chromium toxicity - chromium receptor site competes with iron

Answer 298

A

PO bisphosphonates (osteoporosis treatment)

Caffeine

Phosphate binders

Calcium polycarbophil (bulk-forming fiber therapy - Fibercon)

Cholestyramine (bile acid sequestrant)

Magnesium hydroxide

Miglitol (DM medication)

Oral contraceptives

PPIs

Sodium bicarbonate (antacid)

Tetracyclines (antibiotic)

Levothyroxine (thyroid hormone)

Answer 299

A

Eltrombopag (thrombocytopenia medication)

Vorapaxar (antithrombotic)

Carbamazepine (antiepileptic) → can decrease levels with long term use

Answer 300

A

Epoetin alfa (erythropoietin)

Answer 301

A

Cefdinir (antibiotic)

Ciprofloxacin (antibiotic)

Dolutegravir sodium (HIV antiviral)

Answer 302

A

methyldopa (antihypertensive)

Answer 303

A

May contribute to oxidative reactions that exacerbate tissue damage

May stimulate bacterial proliferation

Answer 304

A

Dextran formulation is preferred to add to PN (dextrose/AA)

Do not add to TNAs as this can destabilize these emulsions

Answer 305

A

Fasting: plasma zinc increases

Infection: zinc is redistributed → hypozincemia
* Secretion of cytokines IL-1 and IL-6 → increase hepatic zinc uptake

Injury: within hours, plasma levels decrease by 10-69%

Answer 306

A

Overall biochemical functions: catalytic, structural, and regulatory

May also have mild antimicrobial and antiinflammatory properties

Answer 307

A

Lipid peroxidation
Apoptosis
Neuromodulation
Cellular proliferation and differentiation
Wound healing
Insulin synthesis and glucose control
Immune function

Answer 308

A

Hydrolyzed from amino acids and nucleic acids via gastric HCl and other enzymes in the small intestine before absorption

Answer 309

A

Reduced gastric acidity can decrease zinc availability for absorption

Answer 310

A

Primarily duodenum and jejunum

Lesser extent in ileum

Answer 311

A

Protein responsible for regulation of zinc absorption

Answer 312

A

GI tract, kidneys, and skin

Answer 313

A

Zinc deprivation
Older adults
Alcoholism
Postoperative patients
Burn patients
Malabsorptive diseases or conditions
Intestinal bypass or resection
Renal disease
Liver disease
Wound drainage
Excessive GI losses (diarrhea, high output fistula)
Sickle cell anemia
Acrodermatitis enteropathica (a disorder of zinc metabolism)
Malignancy
Phytic acid and calcium supplements
Decrease absorption up to 50%
Certain milk proteins may have a negative effect on absorption

Answer 314

A

SKIN
- Rash (periorificial [skin around mouth], perianal, buttocks)
- Impaired wound healing and epithelization

HAIR
Alopecia

EYES
Impaired night vision (2/2 vitamin A deficiency)

NERVOUS SYSTEM
Altered taste and smell

Answer 315

A

Impaired immune function
Hypogonadism
Anorexia
Diarrhea

Answer 316

A

Dietary supplements or accidental ingestion of too much zinc
Skin contact
Breathing in fumes

Answer 317

A

Gastric distress
Nausea
Dizziness
Decreased immune function
Decreased levels of HDL

Answer 318

A

Zinc deficiency → secondary Vitamin A deficiency

High levels of calcium or iron
* Compete with zinc for binding to ligands/chelators necessary for zinc absorption

High levels of zinc (>40 mg/d) → copper deficiency
* Due to increased metallothionein production
* Copper binds strongly to metallothionein; trapped in enterocyte
* Copper deficiency anemia → interferes with iron absorption/metabolism and transport of iron out of cells

Answer 319

A

Tetracycline (antibiotic)
Ciprofloxacin (antibiotic)
Levofloxacin (antibiotic)
Phosphate binders
Calcium polycarbophil (bulk-forming fiber therapy - Fibercon)
Eltrombopag (thrombocytopenia medication)
Ferrous salts

Answer 320

A

Corticosteroids (anti-inflammatory)
Hydrochlorothiazide (antihypertensive)
Propofol (sedative)

Answer 321

A

Oral contraceptive → decrease serum zinc levels

Answer 322

A

Zinc decreases absorption of Dolutegravir sodium (HIV antiviral)

Answer 323

A

Oxidation-reduction and electron-transfer reactions involving oxygen

** Cytochrome C oxidase (Enzyme in the ETC → ATP)

Answer 324

A

Cholesterol metabolism
Glucose metabolism
Formation of melatonin pigment

Answer 325

A

Stores and carries copper from the liver into the bloodstream → tissues

Positive acute phase reactant

Rise in serum level is to increase copper transport to stimulate cuproenzyme synthesis and inactivate inflammation-induced free radicals

Responsible for manganese oxidation and oxidation of ferrous iron (Fe2+) → ferric iron (Fe3+)

Scavenger of free radicals

Answer 326

A

Gastric secretions, HCl, and pepsin → release bound copper in the stomach

Answer 327

A

Duodenum is primary site

Absorption throughout small intestine
Stomach has some degree of copper absorption capacity

Answer 328

A

Protein carriers, albumin, and specific copper transporters from intestinal cell → hepatocytes and Kupffer cells in the liver →

1) Liver enzymes (cytochrome C oxidase, superoxide dismutase)

2) Ceruloplasmin → blood → extrahepatic tissues OR → bile for excretion

Answer 329

A

Feces → aids in regulating copper status

Ex: as copper stores increase, biliary copper excretion increases

Answer 330

A

Malabsorptive disorders (e.g., celiac disease)

Pts recovering from undernutrition associated with chronic diarrhea

Pts recovering from intestinal surgery

Hemodialysis (copper losses can be excessive)

Bariatric surgery (increased risk)

Answer 331

A

SKIN - hypopigmentation

HAIR - hypopigmentation

EYES- Kayser-Fleischer rings (copper colored ring around the iris)

Answer 332

A

Sensory ataxia

Lower extremity spasticity

Paresthesia in extremities (peripheral neuropathy)

Myeloneuropathy

Answer 333

A

Hypochromic, microcytic anemia

Leukopenia

Neutropenia

Hypercholesterolemia

Increased erythrocyte turnover

Abnormal electrocardiographic patterns

Answer 334

A

Wilson’s disease: inherited disorder → too much copper → accumulates in organs
* Can cause cirrhosis

Impaired biliary excretion or cholestasis can cause copper retention in the hepatocyte → oxidative damage

Answer 335

A

MOUTH - metallic taste

OTHER - blood in urine, liver damage

Answer 336

A

High zinc supplementation → hamper copper absorption

Copper deficiency → iron deficiency 2/2 decreased release of iron from the enterocyte

Excess molybdenum → increases urinary copper wasting

Answer 337

A

phytates

dietary fiber

iron

large doses of calcium gluconate

large doses of Vitamin C

Answer 338

A

H2 antagonist or PPIs

Answer 339

A

oral contraceptives

Answer 340

A

Celiac disease: prophylactic supplementation when anemia or neutropenia is present

Caution in administration in patients with hepatic dysfunction (excreted via liver/bile)

PN: risk of iatrogenic hepatic copper overload → potential to do irreparable harm to liver

Answer 341

A

Component of metalloenzymes

Activator of certain enzymes

Answer 342

A

Arginase (urea formation)
Pyruvate carboxylase (CHO synthesis from pyruvate)
Manganese superoxide dismutase (essential prep step in neutralizing free radicals produced from ETC → water)

Answer 343

A

Throughout the small intestine

Answer 344

A

Enters liver via portal circulation → oxidized by ceruloplasmin to Mn3+ → extrahepatic tissues

Answer 345

A

Bile –> feces

Answer 346

A

Rare unless completely absent from diet

Answer 347

A

BONES/JOINTS - abnormal bone and cartilage formation

NERVOUS SYSTEM - ataxia

Answer 348

A

Poor reproductive performance

Congenital abnormalities in offspring

Growth retardation

Defects in lipid/CHO metabolism

Answer 349

A

Hepatobiliary disease (ex: cholestatic liver disease) d/t being almost exclusively excreted via hepatobiliary system

Long-term PN (>30 days) who develop obstruction of biliary duct and unable to excrete

Answer 350

A

Hyperirritability
Violent tendencies
Hallucinations
Disturbances of libido
Ataxia
Mn deposition in the basal ganglia 2/2 perioperative PN following GI surgery
Parkinson-like motor dysfunction (e.g., tremors, difficulty walking, facial muscle spasms)

Answer 351

A

Immune system and reproductive dysfunction
Nephritis
Pancreatitis
Hepatic damage
Testicular damage

Answer 352

A

Iron – competes for similar binding sites, can impair Mn absorption

Answer 353

A

Tetracycline (antibiotic) chelates with Mn → decreased absorption

Answer 354

A

Methionine and cysteine

Selenomethionine: primary dietary form – plant sources

Selenocysteine: animal sources

Answer 355

A

Cofactor in glutathione, iodine, and thyroid metabolism

Some selenium dependent enzymes:

Glutathione peroxidase: eliminates hydrogen peroxide

Iodothyronine deiodinase: key role in regulation of metabolism

Answer 356

A

Urine and feces

Answer 357

A

Cardiomyopathy and skeletal muscle weakness reported in:
- Long-term PN without selenium
- Thermal injury

Statins
* Inhibit 3-hydroxy-3-methylglutaryl CoA reductase → induce myopathy by interfering with synthesis of selenoproteins

Trauma patients
* Depressed serum selenium levels post-injury → decreased thyroxine deiodination which may explain impact on thyroid metabolism

Answer 358

A

Increased susceptibility to mercury exposure

Altered thyroid hormone metabolism

Congestive cardiomyopathy 2/2 Keshan disease

N/V

Answer 359

A

Acute/chronic intake of excess selenium

Answer 360

A

Skin lesions
Hair loss
Nail loss
Tooth decay
Peripheral neuropathy
Fatigue
Irritability

Answer 361

A

Selenium deficiency → decreased production of iodine-dependent selenoprotein deiodinases → limiting role of iodine

Answer 362

A

Eltrombopag (thrombocytopenia medication)

Answer 363

A

Integral component to thyroid hormones thyroxine (T4) and triiodothyronine (T3)

T3 metabolically active form which regulates the rate of cell metabolism and activity and growth in multiple tissues

Answer 364

A

Rapidly absorbed in stomach and upper small intestine

Answer 365

A

Appears in portal blood, rapidly taken up by thyroid (70-80%) for thyroid hormone synthesis

Lesser amounts found in kidneys, salivary glands, other tissues

Answer 366

A

Kidneys main route of excretion

Answer 367

A

Deficiency in iodine →
insufficient T4 →
constant release of TSH →
hyperplasia of thyroid gland (goiter) to more effectively capture iodide from the blood

Answer 368

A

Low salt diets
Consumption of salt from unfortified sources (e.g., sea salt)
Low iodine levels in soil

Answer 369

A

Elevated TSH

Jod-Basedow phenomenon:
Nodular goiter
Weight loss
Tachycardia
Muscle weakness
Skin warmth

Answer 370

A

Deficiency with aggressive/rapid intake of iodine → thyrotoxicosis can occur

Common in older adults

Answer 371

A

Elevated TSH
Depressed thyroid activity

Answer 372

A

Selenium deficiency: T3 and T4 dependent on selenoprotein deiodinases to interconvert between inactive and active forms of thyroid hormone

Cruciferous vegetables: contain goitrogens which compete with iodide for entry into thyroid gland

Answer 373

A

Lithium (antimanic agent)

Answer 374

A

Essential for glucose, protein, and lipid metabolism
–> Required for growth

Potentiates role of insulin

Answer 375

A

Increases in serum glucose → increases in chromium excretion

Suggested that Cr stored in blood is mobilized in response to insulin concentrations → excretion in urine

Answer 376

A

Primarily jejunum (for passive diffusion)

Answer 377

A

Trivalent form of Cr binds competitively with transferrin → blood with iron

Then moves into cells where Cr is transferred from transferrin to chromodulin

Answer 378

A

Urine

DM2 and pregnancy can increase urinary excretion

Answer 379

A

Can result in impaired glucose and amino acid use, increased plasma LDL, peripheral neuropathy

Answer 380

A

PN without chromium supplementation

Answer 381

A

Peripheral neuropathy
Weight loss
Hyperglycemia refractory to insulin
Glycosuria (excess sugar in urine)
Elevated plasma FFA

Answer 382

A

Repeated exposure either through oral ingestion (acute) or skin contact and inhalation

Answer 383

A

Muscle rhabdomyolysis
Liver dysfunction
Renal failure

Answer 384

A

Iron status can be compromised w/ Cr supplementation 2/2 competition for binding sites on transferrin

Serum ferritin levels decrease with Cr intakes at 200 mcg/d

Answer 385

A

Corticosteroids (anti-inflammatories)

Answer 386

A

Role in bone mineralization and hardening of tooth enamel

Helps inhibit and reverse the initiation and progression of dental caries

Stimulates new bone formation → stimulating osteoblasts

May reduce risk for osteoporosis

Some studies suggest it may inhibit calcification of aorta and soft tissue

Answer 387

A

Kidneys (50%)

Deposition in the calcified tissue (bone and developing teeth)

Answer 388

A

1) Non-fluoridated water as primary water source

2) Increased risk of dental caries

Answer 389

A

Chronic excessive fluoride intake

Swallowing fluoridated toothpaste

** Children **

Answer 390

A

EYES - lacrimation (tears)

MOUTH - excessive salivation

BONE - enamel and skeletal bone fluorosis (mottled teeth)

Answer 391

A

Convulsions
Sensory disturbances
Paralysis
Coma

Answer 392

A

N/V/D
Abdominal pain
Pulmonary disturbances
Cardiac insufficiency
Arrhythmias
Weakness

Answer 393

A

Calcium/Magnesium

Answer 394

A

Phosphate binders

Calcium polycarbophil (bulk-forming fiber therapy - Fibercon)

Answer 395

A

Cofactor for metalloenzymes:

1) Aldehyde oxidase
Metabolism of drugs and toxins

2) Xanthine oxidase
Catalyzes the breakdown of nucleotides (precursors to DNA and RNA) to form uric acid, which contributes to the plasma antioxidant capacity of the blood

3) Sulfite oxidase
Transformation of sulfite to sulfate, a reaction that is necessary for the metabolism of sulfur-containing amino acids (methionine and cysteine)

Answer 396

A

Proximal small intestine

Answer 397

A

Mo is transported as Molybdate – loosely attached to erythrocytes

Tends to bind to albumin and a-macroglobulin

Answer 398

A

Excreted by kidneys as molybdate

Answer 399

A

can occur in long-term PN

Answer 400

A

Dislocation of ocular lens
Altered vision
AMS
Attenuated (reduced) brain growth
Neurologic damage
Tachycardia
Tachypnea (rapid breathing)
Elevated methionine
HA
Lethargy
N/V

Answer 401

A

Excessive dietary intake (10-15 mg/d)

Exposure to environmental contamination

Answer 402

A

Rare: hyperuricemia and gout-like symptoms

Answer 403

A

Moderate doses of Mo (0.54 mg/d): associated with copper wasting in urine

Tetrathiomolybdate is compound responsible and is used to treat Cu toxicity (Wilson dz)

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Ch 8: Vitamins & Trace Elements Flashcards

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