Nutritional Disorders PDF

Summary

This document provides an overview of nutritional disorders, including their causes, types, symptoms, and potential complications. It covers a range of conditions, from protein-energy malnutrition to vitamin deficiencies and obesity.

Full Transcript

NUTRITIONAL
DISORDERS
NUTRITIONAL DISEASES

An adequate diet should provide:–
Sufficient energy in the form of carbohydrates, fats and
proteins.

Vitamins and minerals, which function as co-enzymes or
hormones in vital metabolic pathways or, as for the case
of Ca & P, as important structural components.
MAIN NUTRITIONAL DISORDERS
🡪 Obesity
🡪 Kwashiorkor
🡪 Marasmus
🡪 Anorexia nervosa
🡪 Bulimia nervosa
🡪 Vitamin deficiency
🡪 Trace element deficiency
MALNUTRITION
🡪 The World Health Organization defines malnutrition as
"the cellular imbalance between supply of nutrients and
energy and the body's demand for them to ensure
growth, maintenance, and specific functions.“

🡪 Primary: related to diet.

🡪 Secondary: related to:
 –Nutrient malabsorption.
 –Impaired nutrient utilization or storage.
 –Excess nutrient losses.
 –Increased need for nutrients.
PROTEIN-ENERGY MALNUTRITION
🡪 Inadequate intake of protein and calories.
🡪 Two main clinical syndromes:
Marasmus
* starvation in infant with overall lack of
calories.
* somatic protein compartment (skeletal
muscles) affected
Kwashiorkor.
* protein deprivation more severe than deficit
in calories
* visceral compartment (protein stores in liver )
affected
 MARASMUS

🡪 Marasmus is a consequence of protein energy deficiency
characterized by:–
 Wasting of muscles and fat tissue (“skin and
bone”).
🡪 growth retardation

🡪 Serum protein is normal, and there is no edema.

🡪 It can occur at any age and can be easily compensated by
normalizing nutritional supply of proteins and other
nutrients.
:
 Weight is less than 60%of normal.

 Loss of muscle mass and subcutaneous fat 🡪
emaciation of extremities and head appears too
large for body

 Usually there is associated anemia, multivitamin
deficiencies and immune deficiency (T-cell mediated
immunity) 🡪 concurrent infections
KWASHIORKOR
🡪 Kwashiorkor is a childhood protein energy deficiency that
occurs when protein deprivation is greater than reduction
in total calories.

🡪 Typically occurs in children who have been weaned
of the mother’s breast when the second child was
born

🡪 c/c by hypoalbuminemia and generalized
or dependent edema.

🡪 Loss of weight masked by edema

🡪 Usually there is sparing of muscle and subcutaneous fat.
🡪 Other clinical features include:
🡪 FLAKY PAINT appearance of skin (alternating zones of
hyperpigmentation, areas of desquamation and
hypopigmentation)

🡪 Alternating bands of pale and dark hair – FLAG sign

🡪 Enlarged FATTY LIVER

🡪 atrophy and loss of small intestinal villi, leading to
concurrent loss of small intestinal enzymes
🡪disaccharidase deficiency

🡪 Devp of apathy: Lack of interest and Restlessness,

🡪 Loss of appetite

🡪 other vitamin deficiencies, and defects in immunity
Marasmus Kwashiorkor:
KWASHIORKOR MARASMUS
Clinical features Clinical features
 Occurs in children  Common in infants under
between 6 months 3 years 1 year of age
of age
 Growth failure
 Growth failure
 Wasting of all tissues
 Wasting muscles but including muscles and
preserved adipose tissue adipose tissue
 Edema , localized or  Edema absent
generalized, present
 No hepatic enlargement
 Enlarged fatty liver
 Serum proteins normal
 Serum proteins low
 Anemia present
 Anemia present
 Monkey-like face,
 Alternate bands of light protuberant
limbs abdomen, thin
1
1
and dark hair – FLAG sign
KWASHIORKOR MARASMUS
🡪 Morphology 🡪 Morphology
🡪 Enlarged fatty liver 🡪 No fatty liver

3/8/2019
🡪 Atrophy of different 🡪 Atrophy of different
tissues and organs but tissues and organs
subcutaneous fat including subcutaneous

NUTRITIONAL DISORDERS
preserved fat
🡪 Small bowel – mucosal 🡪 Rarely seen

atrophy & loss of villi and
micro villi
🡪 Bone marrow 🡪 Hypoplastic heart
hypoplastic: plastic 🡪 Seen
anemia 🡪 Less marked
🡪 Cerebral atrophy
🡪 Thymic & lymphoid 12

atrophy
KWASHIORKOR AND MARASMUS

3/8/2019
13
DIS
MARASMUS

3/8/2019
14
ONA
L
DIS
PEM IN DEVELOPED WORLD
🡪 Secondary PEM
🡪 Develops in chronically ill, older and bed ridden
patients
🡪 Obvious Signs of secondary PEM include:
 Depletion of subcutaneous fat in arms, chest
wall, shoulders or metacarpal regions

 Wasting of quadriceps and deltoid muscles

 Ankle or sacral edema
CACHEXIA
🡪 PEM in patients with AIDS or advanced
CANCERS is k/a cachexia
🡪 cause extreme wt loss, fatigue, muscle
atrophy, anemia, anorexia, and edema
🡪 Exact cause not known
🡪 Mediators secreted by tumors contribute to
cachexia:
Proteolysis inducing factor
lipid- mobilizing factor
ANOREXIA NERVOSA

🡪 Self induced starvation resulting in marked wt loss
🡪 similar to severe PEM

🡪 In addition effects on endocrine system are:
AMENORRHEA (GnRH secretion
decreases-absence of menstration)
 Symptoms of HYPOTHYROIDISM
 BONE DENSITY decreased
 Dehydration & electrolyte abnormalities

🡪 Major complication: CARDIAC ARRHYTHMIA &
SUDDEN DEATH d/t hypokalemia (low
blood potassium level)
BULIMIA NERVOSA
🡪 Pt binges on food and then induces vomiting
🡪 More common than anorexia nervosa
🡪 No specific signs or symptoms
🡪 Diagnosis depend on psychological assessment
🡪 Major complications occur d/t frequent vomiting &
chronic use of laxatives n diuretics:
 Electrolyte imbalance (hypokalemia) 🡪 cardiac
arrhythmias
 Pulmonary aspiration of gastric contents
 Esophageal and gastric rupture
OBESITY
🡪 Obesity is defined as an accumulation of excess of
adipose tissue that imparts health risk.
🡪 A body wt of 20% excess over ideal wt for age, sex and
height is considered as health risk

Etiology
🡪 Obesity results when calorie intake exceeds
utilisation like in
 Over eating

 Inactivity and sedentary life style
 genetic predisposition to develop
obesity
🡪 Loss of function mutation in leptin (hormone to
maintain body weight)
🡪 Mutation of melanocortin receptor 4(MC4R)
(regulation of food intake)
🡪 Haploinsufficiency of BDNF (brain derived
neurotrophic factor), obesity in WAGR
syndrome (wilms tumor , aniridia, genitourinary
defects, mental retardation)

 diets largely derived from carbohydrates
and fats than protein rich food.

 Secondary obesity hypothyroidism, cushings
disease (excess cortisol), insulinoma (tumor in
the pancreas), and hypothalamic disorders
OBESITY
🡪 How to measure fat accumulation:
Body mass index (BMI: kg/m2):.
🡪 Normal BMI 🡪 18.5 to 25
🡪 25-30 🡪 overweight
🡪 >30 🡪 obese

Skin fold measurements.

Various body circumferences particularly the ratio of the
waist-to-hip circumference.

🡪 Distribution of fat has also an effect: central or
visceral obesity is associated with more risk than
excess accumulation of fat in subcutaneous tissue.
OBESITY
Two basic types of obesity:

A. Life-long obesity:

🡪 Also called hyperplastic obesity.
🡪 Begins in childhood and is characterized by an
increased number of adipocytes on peripheral parts of
the body.

B. Adult onset obesity:

🡪 Also called hypertrophic obesity.
🡪 It is characterized by an increased size of fat cells
and central obesity. Fat accumulates on the trunk.
 HOW DOES THE BODY PREVENT THE
DEVELOPMENT OF OBESITY?
o Balance between calorie intake and expenditure.
o The critical role in this regulation is played by
Leptin.
o Neurohumoral mechanism regulating energy balance –
3 components

1. Peripheral or afferent system 🡪 genertes signals from
various sites. Componenets are:
🡪 Leptin & adiponectin produced by fat cells
🡪 ghrelin from the stomach,
🡪 peptide YY (PYY) from the ileum and colon, and
🡪 insulin from the pancreas.
2. Arcuate nucleus in hypothalamus processes the
signals and generate efferent signals. Consists of
two subsets of firstorder neurons:
🡪 (1) POMC (pro-opiomelanocortin) and CART (cocaine and
amphetamine-regulated transcripts) neurons
🡪 POMC/CART neurons enhance energy expenditure and

weight loss through the production of the anorexigenic α-
melanocyte-stimulating hormone (MSH), and

🡪 the activation of the melanocortin receptors 3 and 4
(MC3/4R) in second-order neurons.

🡪 These second order neurons are in turn responsible for
producing factors such as thyroid releasing hormone (TSH)
and corticotropin releasing hormone (CRH) that increase
the basal metabolic rate and anabolic metabolism, thus
favoring weight loss
 🡪 (2) neurons containing NPY (neuropeptideY) and AgRP
(agouti-related peptide).
🡪 the NPY/AgRP neurons promote food intake (orexigenic

effect) and weight gain, through the activation of Y1/5
receptors in secondary neurons.

🡪 These secondary neurons then release factors such as
melanin-concentrating hormone (MCH) and orexin,
which stimulate appetite.
 These first-order neurons communicate with second-
order neurons in the hypothalmus.
3. Efferent system 🡪 2 pathways🡪 anabolic and
catabolic pathway which controls food intake and
energy expenditure respectively
LEPTIN
🡪 Leptin binds to leptin receptors in the hypothalamus,
increases energy consumption by
 stimulating POMC/CART neurons 🡪 produe anorexigenic
neuropeptide( MSH) and
 inhibiting NPY/AgRP neurons 🡪 produce orexigenic np
🡪 thus suppressing food intake and increasing expenditure
of calories
🡪 Thermogenesis, an important catabolic effect mediated
by leptin, is controlled in part by hypothalamic signals
that increase the release of norepinephrine from
sympathetic nerve endings in adipose tissue.
🡪 In addition to these effects, leptin can function as a
proinflammatory cytokine and participates in the
regulation of hematopoiesis and lymphopoiesis.
ADIPONECTIN

🡪 called as “fat-burning molecule” and the
“guardian angel against obesity,” directs fatty
acids to muscle for their oxidation.
🡪 It decreases the influx of fatty acids to the liver and
the total hepatic triglyceride content
🡪 decreases the glucose production in the
liver, causing an
🡪 increase in insulin sensitivity and
🡪 protecting against the metabolic syndrome
GUT HORMONES
🡪 Gut peptides act as short-term meal initiators and
terminators.
🡪 They include ghrelin, PYY, pancreatic polypeptide,
insulin, and amylin among others.

🡪 Ghrelin is produced in the stomach and in the arcuate
nucleus of the hypothalamus.
🡪 It is the only known gut hormone that increases food
intake (orexigenic effect).
🡪 stimulates NPY/AgRP neurons to increase food intake.
🡪 Ghrelin levels rise before meals and fall between 1 and
2 hours after eating.
🡪 In obese individuals the postprandial suppression of
ghrelin is attenuated and may contribute to overeating
🡪 PYY is secreted from endocrine cells in the ileum
and colon.

🡪 Plasma levels of PYY are low during fasting and
increase shortly after food intake.

🡪 levels of PYY generally decrease in individuals
with the Prader-Willi syndrome (caused by loss
of imprinted genes on chromosome 15q11-q13), a
disorder marked by hyperphagia (unsatisfied
drive to consume food) and obesity.

🡪 These observations have led to ongoing work to
produce PYYs for the treatment of obesity.
🡪 Amylin,
🡪 peptide secreted with insulin from pancreatic β-cells
that
🡪 reduces food intake and weight gain, is also being
evaluated
🡪 for the treatment of obesity and diabetes.

🡪 Both PYY and amylin act centrally by
stimulating POMC/CART neurons in the
hypothalamus, causing a decrease in food
intake.
ADVERSE CONSEQUENCES OF
OBESITY
1. Hyper insulinaemia and insulin resistance 🡪Non-
Insulin dependant diabetes (type 2 DM)

2. Hypertension

3. Hyper triglyceridemia and lowHDL
🡪Atherosclerosis🡪 Coronary artery disease

4. Cholelithiasis

5. Non aloholic fatty liver disease
6. Hypoventilation syndrome / pickwickian syndrome
 c/c by Hypersomnolence, both at night and during the
day,
 is often associated with apneic pauses (not breathing
for 20s or longer) during sleep
(sleep apnea),
 polycythemia, (increased concentration of red blood
cells) and
 right-sided heart failure (cor pulmonale).

7. Cancer

8. Osteoarthritis
OBESITY
DISORDERS OF VITAMINS
VITAMINS
🡪 Fat soluble vitamins
a) vit A
b) vit D
c) vit E
d) vit K
🡪 water soluble vitamins
a) vit B complex
b) vit C
 VITAMIN DEFICIENCY STATES
Water solubleDietary sources Consequence of
Vitamin deficiency
B1 (Thiamine) Cereals , milk, eggs, fruits, yeast Beriberi, Neuropathy, Cardiac
extract failure, Kosakoff’s psychosis,
Wernicke’s encepahlopathy
B2 (Riboflavine) Cereals , milk, eggs, fruits, liver Ariboflavinosis (Mucosal fissuring,
Cheilosis and Glossitis,
Angular stomatitis)
B6 (Pyriodoxine) Cereals , milk, meat, fish Cheilosis, glossitits,
Neuropathy, Sideroblastic
anemia
B12 (Cobalamin) Meat, fish, egg, cheese Megaloblastic anemia, Subacute
combined degeration of spinal cord

Folate (B9) Green vegetables, fruit Megaloblastic anaemia , Neural tube
defects, Mouth ulcers,
Villus atrophy of small gut
Niacin (nicotinic acid) Meat, milk, egg, peas, beans, Pallegra: 3 Ds
(B3) yeast extract Dermatitis, Diarrhoea, Dementia

C (ascorbic acid) Citrus fruits, green vegetables Scurvy, Swollen bleeding gums,
Bruising and bleeding
PELLAGRA

3/8/2019 NUTRITIONAL DISORDERS
PELLAGRA

3/8/2019 NUTRITIONAL DISORDERS
 VITAMIN DEFICIENCY STATES
Fat soluble Dietary sources Consequence of
Vitamin deficiency
A β-carotenes in carrots etc Vit. A Night blindness,
(retinol) in fish, eggs, liver, margarine xerophthalmia,
,squamous metaplasia,
infctns mainly measles
D Rickets ( children)
(calcitriol) Milk, fish, eggs, liver Osteomalacia ( adults)

Hypocalcemic tetany
E Cereals, eggs, vegetable oils Neuropathy,
(α- tocopherol) Anemia(reduced red
cell life span)
K Blood coagulation
Vegetables, liver
Defects
VITAMIN A
🡪 The major functions of vitamin A are
maintenance of normal vision, regulation of cell
growth and differentiation, and regulation of
lipid metabolism.

🡪 Vitamin A is the name given to a group of
compounds that include retinol , retinal ,and
retinoic acid , which have similar biologic activities.

🡪 Retinol is the chemical name given to vitamin A. It
is the transport form and, as retinol ester, also
the storage
🡪 Vitamin A is a fat-soluble vitamin, and its absorption
requires bile, pancreatic enzymes, and some level of
antioxidant activity in the food.

🡪 Retinol (generally ingested as retinol ester) and β-
carotene are absorbed in the intestine,where β-carotene
is also converted to retinol.

🡪 Retinol is then transported in chylomicrons to the liver for
esterification and storage.

🡪 Uptake in liver cells takes place through
the apolipoprotein E receptor.

🡪 More than 90% of the body’s vitamin A reserves are
🡪 Retinol esters stored in the liver can be mobilized;
before release, retinol binds to a specific retinol
binding protein (RBP), synthesized in the liver.

🡪 The uptake of retinol/RBP in peripheral tissues
is dependent on cell surface receptors specific
for RBP.

🡪 After uptake, retinol binds to a cellular RBP, and the
RBP is released back into the blood.

🡪 Retinol may also be stored in peripheral tissues as
retinol ester or may be oxidized to form retinoic
acid,
FUNCTIONS OF VITAMIN A
🡪 Maintenance of normal vision.

🡪 Cell growth and differentiation. Vitamin A maintains
differentiation of mucus-secreting epithelium;
 when a deficiency state exists, the epithelium
undergoes squamous metaplasia (noncancerous,
benign), differentiating into a keratinizing (formation of
keratin polypeptides and polymerization) epithelium

🡪 Metabolic effects of retinoids
 key regulators of fatty acid metabolism, including fatty
acid oxidation , adipogenesis, and lipoprotein
metabolism.
🡪 Host resistance to infections.
 Vitamin A supplementation can reduce morbidity and
mortality from some forms of diarrhea, and in preschool
children with measles, and improve the clinical
outcome.

 The beneficial effect of vitamin A in diarrheal
diseases may be related to the maintenance and
restoration of the integrity of the epithelium of the
gut.

 ability to stimulate the immune system,
🡪 photoprotective and antioxidant property
VITAMIN A DEFICIENCY
🡪 Eye changes:
earliest manifestations is impaired vision, particularly in
reduced
light (night blindness).

 Persistent deficiency gives rise to epithelial metaplasia and
keratinization.

 The most devastating changes occur in the eyes and are referred
to as xerophthalmia (dry eye).
 First, there is dryness of the conjunctiva (xerosis conjunctivae)
as the normal lacrimal and mucus-secreting epithelium is replaced
by keratinized epithelium.

 This is followed by a buildup of keratin debris in small opaque
plaques (Bitot spots)
 Progresses to erosion of the roughened corneal surface, softening
🡪 Squamous metaplasia in respiratory and urinary
tract predisposing to infections and renal stones
respectively

🡪 Hyperplasia and hyperkeratinization of the
epidermis with plugging of the ducts of the adnexal
gland produce follicular or papular dermatosis.

🡪 Another very serious consequence is immune
deficiency, which is responsible for higher mortality
rates from common infections such as measles,
pneumonia, and infectious diarrhea.
VITAMIN A TOXICITY

🡪 The symptoms of acute vitamin A toxicity include
 Headache
 Dizziness
 Vomiting
 stupor and
 blurred vision,
🡪 symptoms may be confused with those of a brain
tumor (pseudotumor cerebri).
🡪 Chronic toxicity is associated with weight loss, anorexia,
nausea, vomiting, and bone and joint pain.
🡪 Retinoic acid stimulates osteoclast (cells that degrade
bone) production and activity, leading to increased
bone resorption and high risk of fractures.
VITAMIN D
🡪 The major function of the fat-soluble vitamin D
is the

🡪 maintenance of adequate plasma levels of
calcium and phosphorus to support metabolic
functions, bone mineralization, and
neuromuscular transmission.

🡪 Vitamin D is a key regulator of calcium and
phosphate homeostasis
🡪 The major source of vitaminD for humans is its
endogenous synthesis from a precursor,7-
dehydrocholesterol, in a photochemical
reaction that requires solar or artificial UV light
in the range of 290 to 315 nm (UVB radiation).

🡪 This reaction results in the synthesis of
cholecalciferol, known as vitamin D3.

🡪 Vitamin D is produced from 7-dehydrocholesterol in
the skin or is ingested in the diet.
🡪 It is converted in the liver into 25(OH)D, and in
kidney into 1,25(OH)2D (1,25-dihydroxyvitamin D),
the active form of the vitamin.

🡪 1,25(OH)2D stimulates the expression of RANKL
(receptor activator of nuclear factor kappa beta (NFkB
ligand)), an important regulator of osteoclast
maturation and function, on osteoblasts, and
enhances the intestinal absorption of calcium and
phosphorus in the intestine
 VITAMIN D DEFICIENCY
🡪 Causes:
 lack of dietary vit D
 inadequate exposure to sunlight
 intestinal malabsorption of fat
 impaired hydroxylation due to hepatic and renal diseases

🡪 Mechanism:
 lack of vit D impairs mineralisaton of the growing skeleton

🡪 Signs of deficiency
Rickets (children)
Osteomalacia (adults)
Hypocalcemic etany
SIGNS OF RICKETS

Skeletal deformities –
bow legs & lumbar
lordosis
THORACIC CHANGES IN RICKETS
🡪 Deformation of the chest results from overgrowth of
cartilage or osteoid tissue at the costochondral
junction, producing the “rachitic rosary.”

🡪 The weakened metaphyseal areas of the ribs are
subject to the pull of the respiratory muscles and
thus bend inward, creating anterior protrusion of the
sternum (pigeon breast deformity).

🡪 Harrisons sulcus (horizontal groove along lower
border of thorax)
SKULL CHANGES
🡪 During the nonambulatory stage of infancy, the
head and chest sustain the greatest stresses.

🡪 The softened occipital bones may become
flattened, and the parietal bones can be buckled
inward by pressure; with the release of the
pressure, elastic recoil snaps the bones back into
their original positions (craniotabes).

🡪 An excess of osteoid produces frontal bossing
and a squared appearance to the head.
MORPHOLOGY OF RICKETS
Vitamin D deficiency in both rickets and osteomalacia
results in an excess of unmineralized matrix. The
following sequence occurs in rickets:
🡪 Overgrowth of epiphyseal cartilage due to
inadequate provisional calcification and failure of
the cartilage cells to mature and disintegrate

🡪 Persistence of distorted, irregular masses of
cartilage, which project into the marrow cavity

🡪 Deposition of osteoid matrix on inadequately
mineralized cartilaginous remnants
🡪 Disruption of the orderly replacement of cartilage by
osteoid matrix, with enlargement and lateral
expansion of the osteochondral Junction

🡪 Abnormal overgrowth of capillaries and fibroblasts
in the disorganized zone resulting from
microfractures and stresses on the inadequately
mineralized, weak, poorly formed bone

🡪 Deformation of the skeleton due to the loss
of structural rigidity of the developing bones
a. normal costochondral junction of a young child illustrating formation of cartilage
palisades and orderly transition from cartilage to new
bone
b. detail of a rachitic costochondral junction in which the palisades of
cartilage is lost. darker trabeculae are well-formed bone; paler trabeculae
consist of uncalcified osteoid.
 VITAMIN C DEFICIENCY
🡪 Causes: Dietary lack of fresh fruits and vegetables.
🡪 Mechanism: impaired collagen synthesis ( Vitamin C is
needed for collagen synthesis and collagen cross-linking
and tensile strength.)

🡪 Vit c def l/t to dev of SCURVY c/c by bonedisease
in growing children and by hemorrhages and
healing defects in both children and adults.

🡪 Vascular pattern –gingival bleeding, petechiae and
echymoses
🡪 Skeletal changes –soft bones, growth retardation
🡪 Delayed wound healing
LIST OF DEFICIENCES OF
ESSENTIAL MINERALS
🡪 Iron - microcytic hypochromic anemia.
🡪 Iodine- hypothyroidism, goiter, growth retardation.
🡪 Copper- neuromuscular disorders.
🡪 Zinc- acrodermatitis enteropathica (rash around
eye mouth nose and anus), infertility, growth
retardation, anorexia and diarrhoea
🡪 Fluoride- dental caries.
🡪 Selenium – keshan disease🡪 congestive
cardiomyopathy d/t combination of dietary
deficiency of Se and presence of mutated strain
of Coxsackie virus