Patho: Final Exam Review PDF

Summary

This document is a review of gastrointestinal, endocrine, and infectious diseases, focusing on pathophysiology, digestion, absorption, and associated conditions such as peptic ulcers and diarrhea. It provides detailed information on the GI tract, stomach, intestines, and relevant processes. This review material is intended for final exam preparation.

Full Transcript

Patho: Final Exam Review
GI, Endocrine, & Infectious Disease
Gastrointestinal
Pathophysiology
Intestines
The GI tract has 4 layers, and has neuronal
innervation
- Serosa (Outermost layer)
- Muscularis (longitudinal layer  myenteric
plexus  circular layer)
- Submucosal plexus
- Submucosa
- Mucosa (innermost layer)

The enteric plexus is made up of the myenteric
and submucosal plexus
- Submucosal plexus is also called Meissner’s
plexus
Peyer’s Patches in the mucosa are key - Myenteric plexus is also called Auerbach’s
players in immune surveillance for the GI tract plexus
Small Intestine
3 layers: duodenum, Jejunum, Ileum
Duodenum
- Tall layer of mucosa
- Many villi to increase surface area
for nutrient absorption
- Duodenum does the most
amount of absorption
Jejunum
- Tall villi but less than in duodenum
Ileum
- Short, tightly packed villi
Stomach
The stomach has 3 muscle layers
○ Longitudinal
○ Circular
○ Oblique  this muscle layer helps
churn food to aid with digestion
The LES (lower esophageal
sphincter) strops gastric contents
from refluxing into the esophagus
The pyloric sphincter prevents
movement of food into the
duodenum until it’s been churned
and mixed with stomach acid
 Stomach Lining
Gastric pits: small depressions in epithelial
lining of the stomach. Each pit has a
gastric gland at the bottom which contains
different cell types

Cell Type Product
Mucous neck cells Mucin – is taken into lining of gastrin mucosa
to create protective mucus layer
Chief cells Pepsinogen – is cleaved into pepsin which is
the enzyme that breaks down proteins in the
stomach
Parietal cells Hydrochloric acid and intrinsic factor

G cells Gastrin – stimulates acid secretion and
contraction of the intestines
Endocrine cells Somatostatin and histamine
GI Tract Circulation
Oxygenated blood circulates to the
organs of the GI tract via branches of
the abdominal aorta
○ Hepatic artery  liver
○ Celiac artery  stomach, spleen,
pancreas
○ Superior mesenteric artery 
pancreas, small intestine, proximal
colon
○ Inferior mesenteric artery  distal
colon, rectum
Deoxygenated blood from all GI
organs drains into the portal vein,
which is then carried to the liver
Liver = major glycogen storage
Process of Acid Secretion
Gastric acid secretion is stimulated by
○ Vagal nerve stimulation – stimulation by acetylcholine
causes acid secretion
○ Gastrin – a hormone from G cells in the stomach
○ Histamine – binds to H2 receptors and stimulates secretion
Gastric acid secretion can be inhibited by
○ H2 antihistamines
○ Short-term use of PPIs
The rate of gastric acid secretion is different when
fasting vs eating
○ Fasting = very little acid secretion
Low amount of Cl- and H+ in the acid
Higher amounts of Na+ and K+
Gastric pH sits at 5 to 5.5 usually
○ Eating = stimulates LOTS of HCL secretion
Low amounts of Na+ and K+, more H+ and Cl- in the acid
Gastric pH is around 1.5
Process of HCl Production
HCl is made by the parietal cell
CO2 in the blood diffuses into
parietal cell and combines with H2O
 forms carbonic acid (H2CO3)
Carbonic anhydrase cleaves carbonic
acid into bicarb and a proton ion
○ Bicarb is secretes back into the blood
in exchange for a Cl-
○ Proton is secretes into the stomach
lumen by the H-K-ATPase pump
In the stomach lumen, H+ and Cl-
combine to form HCl
Peptic Ulcers
Peptic ulcers occur when there is an imbalance between
damaging (acid) and protective (mucosal) forces
Duodenal ulcers
○ Most found in first portion of duodenum
○ Caused by hypersecretion of acid, leading to injury
○ H. pylori = MCC
○ Patients feel better when they eat because food neutralizes
the acidity
Gastric ulcers
○ Caused by deficiency in mucin production to protect the stomach
lining
○ NSAIDs = MCC
○ Patients feel worse with eating because food stimulates acid
secretion
Digestion
Digestion and Absorption of Carbs
Begins in the mouth with the
secretion of salivary amylase
which breaks carbohydrates into
polysacchardies
Pancreatic amylases travel
through the pancreatic duct to the
duodenum and aid in digestion
Finally, enzymes in the brush
border of the small intestine break
polysaccharides into
monosaccharides
Nutrients can now be absorbed
into bloodstream by a sodium-
glucose cotransporter
Digestion and Absorption of Proteins
Pepsin and HCl in the stomach do
most of the work breaking proteins
into proteoses and peptones
Pancreatic enzymes digest the
proteoses and peptones further
Enzymes in brush border of small
intestine digest these protein
products into amino acids
Amino acids are absorbed via
proton amino acid antiporter and
sodium-amino acid symporter
into the villi and transported to the
liver
Digestion and Absorption of Fats
Fats are the most difficult to absorb
Starts when the emulsifying agents
in bile cleave fatty acids to make
them more soluble
Pancreatic lipase breaks the fats into
monoglycerides and glycerol
○ Monoglycerides are absorbed
through lacteals and are
transported to the liver through
lymphatic circulation
○ Glycerol and short chain fatty
acids are absorbed by capillaries
in the villi and go to the liver via the
portal vein
 Each section of the GI tract
has specific nutrients it
absorbs
○ Stomach absorbs alcohol
○ The duodenum absorbs most
nutrients (due to tightly packed
villi providing more surface area
for digestion)
○ Ileum absorbs vitamin B12
Absorption and Secretion
Electrolyte Transport
Absorption = moving materials from the GI
tracts into the ECF
Secretion = moving material from the ECF
into the lumen of GI tract
Electrolyte transport in duodenum and jejunum
○ Sodium: proton exchanger
○ Sodium: chloride transporter
○ Sodium: glucose cotransporter  targeting
this transporter with supplements such as
Pedialyte is the primary way we provide
oral rehydration in kids with volume
deficits
○ Duodenum and jejunum are considered to
have “leaky epithelium” because H2O
and electrolytes move through gap
junctions
Electrolyte Transport
Electrolyte transport in the terminal
ileum and colon is primary done by
○ Chloride: bicarb exchanger
○ Sodium: chloride cotransporter
○ Diarrhea causes the loss of bicarb in the
feces because of bicarb secretion in the
ileum/colon
Diarrhea can cause metabolic
acidosis from excessive bicarb
loss
The terminal colon has a sodium
channel for absorption
Diarrhea
Definition: increase in stool mass, fluidity, or frequency. Usually > 200
grams per day
4 types
○ Secretory: isotonic stool. Persistent and does not go away with fasting
Ex: some bacterial infections, such as cholera
○ Osmotic: excess water is drawn into the bowels from solutes that inhibit normal water
and electrolyte absorption
Ex: laxatives, gallbladder removal, lactase deficiency
○ Malabsorptive: inability to absorb nutrients properly in the small intestine, but WILL
IMPROVE WITH FASTING
Ex: Celiac disease
○ Exudative: Purulent, bloody stool that does NOT IMPROVE with fasting
Ex: Inflammatory Bowel DIsease
Bacterial Causes of Diarrhea
The most important
things for you to know are
modes of transmission
and symptoms
Cholera “rice water
stools”
Enterotoxigenic E. Coli
“Traveler’s Diarrhea”
Enterohemorrhagic E. coli
– Bloody diarrhea and
HUS in children. Do not
treat with abx
C. diff – Foul smelling
diarrhea after a course of
abx treatment
Cholera -= Prototype for Secretory Diarrhea
Cholera toxin has an alpha and
beta subunit
The cholera toxin stimulates the
enzyme adenylate cyclase to
convert ATP  cAMP
○ This opens the chloride channel in the
intestinal lumen
Chloride moves out of the
intracellular environment into the
intestinal lumen
○ Water follows, filling up the lumen
End result: profuse watery
diarrhea (rice water stools)
Celiac Disease = Prototype for Malabsorptive Diarrhea

Celiac disease is an autoimmune
disease
Ingested gluten is metabolized into
gliadin
Gliadin moves across mucosa and is
deamidated by tTG
Deamidated gliadin is taken up by
APCs and presented to T cells 
stimulates B cells to make anti-
gliadin antibodies
Antigen on T cell binds to MIC-A
receptor  causes loss of height of
villi and crypt elongation which
causes thinning and loss of intestinal
epithelium
Inflammatory Bowel Disease
Mechanism of IBD
Cause not exactly known but likely familial
Mechanism
○ Certain bacteria permeate through the epithelium
more readily than others → taken up by dendritic
cells, degraded, and antigens are presented to CD4
and CD8 cells
○ TH2 and TH17 → humoral B cells
○ TH1 → upregulates macrophages and cytotoxic
T cells that cause damage to the epithelial
cells, allowing more bacteria to cross
Use immunosuppressants to inhibit the T cell
response and improve inflammatory symptoms
Meds bind to TNF receptor on the epithelia to
stop the increase in permeability.
Need to know: TNF alpha is the major
component of this inflammatory process
Crohn’s Disease vs Ulcerative Colitis
Crohn’s Disease: skip lesions
throughout the entire bowel but mostly
the ileum, transmural inflammation, may
form granulomas and fistulas,
“cobblestone” appearance
Ulcerative colitis: affects ONLY the
colon (starts at anus/rectum and extend
proximally), no skip lesions, higher risk of
colon cancer, may form toxic megacolon,
“lead pipe appearance” from loss of
haustra
GI Motility
Step 1 - Swallowing
Swallowing
○ When not swallowing:
UES is contracted
Epiglottis is up
Glottis is open
○ When swallowing:
Larynx moves up, tipping the epiglottis OVER the glottis
UES relaxes and peristalsis allows food to propagate down the pharynx
Peristalsis happens from contraction of longitudinal and circular muscles
Step 2 – Gastric Motlity
Gastric Motility is divided into 2
parts
○ Accommodation
Fundus of stomach +
proximal ⅓ of corpus
Allows food to enter
stomach
○ Emptying
Remaining corpus,
antrum, and pylorus
Allows food to digest and
pass into duodenum
Step 3 – Small Intestine Motility
Most of the work is done by the duodenum
Duodenum serves 3 general purposes
○ Absorb extrinsic enzymes from pancreas and gallbladder, then use
these enzymes to form chyme
○ Secrete enzymes and waste products once everything has been
absorbed
○ Propagate remnant down the jejunum and eventually the terminal
ileum
Once chyme enters the duodenum, 3 movements happen
○ Propagation: wavelike muscle contraction (peristalsis)
○ Segmentation: circular muscle constricts the intestine into small
segments, sloshing chyme back and forth
○ Pendular: longitudinal muscle relaxes and contracts, causing a small
portion of the intestine to shorten and lengthen
Step 4 – Colonic Motility
The colon transports waste and absorbs water/ some nutrients
The colon contracts to
○ Make stool
Repetitive, non-propulsive contractions to mix waste into stool form
○ Propagate stool forward
Large coordinated contractions to move stool from colon into rectum
Motility Disorders
Esophageal dysmotility Colonic Dysmotility
○ GERD ○ Constipation
○ Achalasia ○ Diarrhea
○ Dysphagia
○ Strictures
Stomach dysmotility
○ Gastroparesis
Colon Cancer
Need to Know!
You should
memorize the
driving mutations
at each stage
progressing to
colon cancer (in
the boxes)
Liver, Bile, and Bilirubin Metabolism
Liver
Functions
○ Make bile
○ Make proteins (albumin) for blood plasma
○ Make cholesterol
○ Store glycogen
○ Clear toxins from the blood
○ Regulate clotting by making clotting factors
○ Process hemoglobin, store iron
Anatomy
○ Functional unit is the hepatocyte, centered around
central veins to drain filtered blood
Also drain bile into bile canaliculi  goes to
gallbladder for storage
Bile
Made in the liver and stored in the
gallbladder
Bile is made up of
○ Bile salts
○ Bilirubin
○ Water
○ Electrolytes
○ Phospholipids
Function of Bile Salts
Bile salts are the most important component of bile
They have 3 functions
○ Emulsify fats
Pancreatic lipases separate bile salts and lipids
Lipids are absorbed in the jejunum
Bile salts are absorbed in the Terminal Ileum (95% recycled)
○ Cholesterol Excretion
Bile acid resins prevents reabsorption (cholestyramine, colestipol,
colesevelam)
○ Antimicrobial
Disrupt cell membranes
Less bile=more bacteria
 Bilirubin Metabolism
Bilirubin is a major part of bile
Bilirubin is a byproduct of red blood cell breakdown
○ RBCs develop membrane deformities as they age
○ The deformities are recognized by reticuloendothelial cells
in the spleen, who mark RBCs for destruction
○ RBCs are broken down and release hemoglobin, which is
broken down into heme and globin
○ Heme is converted to biliverdin, which becomes
unconjugated bilirubin (unconjugated means lipid soluble,
water insoluble)
○ Unconjugated bilirubin is combined with glucuronic acid in
the liver to make it water soluble
○ The new conjugated (water soluble) bilirubin is
excreted with bile into small intestine
Conjugated bilirubin is excreted in stool
Conjugated bilirubin can also be converted to
urobilinogen by bacteria, which is excreted in feces
and urine
Splanchnic Circulation
Splanchnic circulation is the blood flow to GI organs
○ Blood is supplied by celiac artery, SMA, and IMA
○ Blood is drained by portal vein, which sends blood to the liver
○ The liver drains processed deoxygenated blood via hepatic veins to the inferior
vena cava
Splanchnic Circulation and Portal Hypertension
Cirrhosis
Cirrhosis is a chronic liver disease
occurring when healthy liver tissue is
replaced by scar tissue (fibrosis)
Inflammation and production of Il-1,
TNF, and TGFB stimulate stellate
cells to differentiate into
myofibroblasts
The myofibroblasts produce collagen 
causes progressive fibrosis
Kupffer cells release cytokines that
promote hepatocyte death
Gallstones and Cholecystitis
Gallstones Acute cholecystitis
○ 90% of cases are caused by stones in
○ MC are cholesterol stones gallbladder blocking cystic duct
Form when there is too much Cause distention and inflammation of
fat in the bile or when there is gallbladder
10% of cases are acalculous and
bile stasis from improper idiopathic
gallbladder emptying ○ Clinical picture
○ Pigment stones Continuous RUQ pain radiating to right
scapula
Caused by conditions that Fever
produce excess bilirubin N/V
Black = alcohol excess Leukocytosis
Brown = parasite
Chronic cholecystitis
○ 95% of patients will also have gallstones
infections ○ Chronic inflammation of gallbladder
Gallstone (cholelithiasis) pain is ○ Patients are usually minimally symptomatic
○ “porcelain gallbladder” on Xray = increased risk
known as biliary colic of gallbladder cancer
○ Intermittent RUQ pain, usually worse
after a fatty meal
Pancreas
Pancreatic Function
Endocrine function
○ Islet cells produce insulin and glucagon
Exocrine function
○ Acinar cells produce enzymes to break down proteins and fat for digestion
Leptin and Ghrelin
Leptin, ghrelin, and adiponectin help the body balance caloric intake
and caloric expenditure
Leptin = increases energy consumption (catabolism)
○ Decreases weight gain and inhibits desire to eat
Ghrelin and Pyy molecules = stimulate fat buildup (anabolism)
○ Encourage feeding desire
Adiponectin = hormone that inhibits aging
○ Increases energy expenditure
○ A beneficial hormone
Endocrinology
Brief Overview
❏ Hormone: substance produced that acts
on distant cells through delivery in the
bloodstream
❏ 2 Modes of action
❏ Cell Membrane Receptors–Non-steroid
Hormones
❏ Tyrosine kinase (insulin, EGF, PDGF,
VEGF)
❏ Cytokine receptors (GH)
❏ G-Protein (PTH, Vasopressin, FSH, LH)
❏ Nuclear Receptors–Steroid Hormones
❏ Cortisol, aldosterone, calcitriol, estradiol,
progesterone, testosterone
❏ Regulation
❏ Feedback loops (positive and negative)
Feedback Loop

❏ Negative feedback mechanisms are the most common
❏ They work to maintain a target level (equilibrium)
❏ Good thing when it comes to homeostasis!
❏ Ex. Pancreas relies heavily on (-) feedback to regulate blood glucose
levels
❏ Positive feedback mechanisms move a system AWAY from equilibrium
❏ Not very common because your body doesn’t like extreme conditions
❏ Ex. Childbirth- uterine stretch receptors are activated→brain sends
signal to release oxytocin→ oxytocin causes uterine muscles to
continue contracting
Hypothalamic/Pituitary Axis = “Master Gland”

❏ This control center in the brain secretes hormones that have
direct effects on tissues
❏ Also secretes hormones that regulate the production and secretion of hormones in
other glands.
❏ The hypothalamic/pituitary axis coordinates most endocrine and
nervous system messages
Anterior Pituitary Posterior Pituitary
Glandular tissue that secretes substance Neuronal tissue
into the blood Nerve fibers
No nerve fibers going here
Its own portal venous system
Obj. Differentiate the action of steroid and
nonsteroid hormones on the target cell.

❏ Steroid and nonsteroid hormones differ in how they cause the
target cells to respond.
❏ Steroid hormones enter the target cells, as they can easily
pass through the cell membrane.
❏ Non-steroid hormones cannot easily pass through the cell
membrane, so they attach instead to receptors on the surface of
the cell
Hypothalamic Pituitary Abnormalities…
HYPERfunction HYPOfunction
❏ Almost always due to an ❏ Hemorrhage/Infarction
adenoma (hormone-secreting ❏ Apoplexy, Sheehan
mass) Syndrome
❏ Prolactinoma: loss of inhibition ❏ Inflammatory/Other
by dopamine, mutations in
❏ Sarcoidosis. TB
Protein kinase A and MEN-1
❏ GH mutations of receptor or ❏ Mass Compression
gain of fxn mutation of Gs
protein (increase cAMP),MEN-1
❏ ACTH: mutations of P27 protein,
MEN-1
Symptoms of Pituitary Mass Effect

Bitemporal hemianopia from
mass effect compression on optic
chiasm
Headache
Increased ICP
specific presentations are from
over/underproduction of
hormone(s)
Prolactinoma
❏ Clin Ft: galactorrhea, amenorrhea, infertility, menorrhagia
(females), testicular atrophy and sexual dysfunction (males)
❏ Dx: measure prolactin levels and imaging (MRI pituitary)
❏ Tx: Dopaminergic agents (bromocriptine, cabergoline) or surgery
(transsphenoidal hypophysectomy)
Growth Hormone Abnormalities
❏ Clin Ft:
❏ Overproduction: gigantism/acromegaly
❏ Underproduction: energy loss, malaise, depression
❏ Dx:
❏ Overproduction: measure GH and imaging
❏ Underproduction: evoke GH response (insulin-induced hypoglycemia or arginine +
GHRH)
❏ TX:
❏ Overproduction: surgery, radiation, octreotide
❏ Underproduction: GH
Adrenal Pathophysiology
Layers of the Adrenal Cortex
ACTH actions on adrenals
❏ ACTH stimulates the adrenal
gland and regulates
glucocorticoids only
❏ Has no effect on
mineralocorticoids or sex
hormones
Cushing’s Disease ↓CRH
↑ACTH
↑Cortisol

Diagnose
○ Measure AM and PM cortisol
(most in the cortisol in the
AM, least amount in PM)
○ dexamethasone suppression
test: ↓CRH ↓ACTH
↓cortisol
Treatment
○ surgery, radiation
Cushing’s Syndrome
↓CRH
↓ACTH
↑cortiso
l
Dx
○ AM and PM cortisol (most in the
AM, least amount in PM)
○ dexamethasone suppression
test: ↓CRH ↓ACTH ↑cortisol
Treatment
○ surgery, radiation
Addison’s Disease (Adrenal Insufficiency)
↑CRH
↑ACTH
↓cortiso
Presentation l
○ Weight loss, malaise, hypotension,
Addisonian crisis (injury, inf. Normally
more cortisol to overcome stress)
○ D/t adrenal glands not producing enough
cortisol
Dx
○ Serum cortisol levels (low)
○ cortrosyn (synthetic analog of ACTH)
stimulation test: ↓cortisol **
○ methampyrone stimulation
Treatment
○ Need glucocorticoid AND
mineralocorticoid replacement daily
○ hydrocortisone IV if under stress
conditions

1°
ACTH Abnormalities
❏ Clin Ft:
❏ Overproduction: Cushing Syndrome or Disease- central obesity, proximal muscle
weakness, glucose intolerance, moon facies, buffalo hump, striae, osteopenia,
HTN
❏ Underproduction: Addison’s Disease-weight loss, malaise, hypoTN
❏ Dx:
❏ Overproduction: am and pm cortisol, dexamethasone suppression test
❏ Underproduction: Cortrosyn stimulation test, metyrapone stimulation
❏ Tx:
❏ Overproduction: may be ectopic-surgery, radiation
❏ Underproduction: cortisol replacement
❏ Basal 20 mg in am and 10 mg in pm
❏ Stress-hydrocortisone 100 mg q8 hours intravenous
Thyroid Pathophysiology
 Thyroid
TPO: iodination of
TSH binds to TSHR → the thyroid
Stimulates production of hormone
thyroglobulin in Golgi to be precursors
transported to lumen 
Upregulates the uptake of
iodine for synthesis of
thyroid hormone Pendrin: transports
iodine into the
lumen

**you need iodine
for synthesis of
thyroid hormone
-if iodine deficient,
can’t make thyroid
hormone
TSH Abnormalities
❏ Clin Ft.
❏ Overproduction: RARE-
thyromegaly,
hyperthyroidism
❏ Underproduction: COMMON-
hypothyroidism
❏ Tx:
❏ Overproduction: surgery,
radiation, octreotide
❏ Underproduction: thyroid
hormone replacement
(levothyroxine)
Hyperthyroidism - Grave’s Disease
Symptoms
○ Weight loss, nervousness, palpitations, tremor, weakness,
bowel frequency
Signs
○ Proptosis, tachycardia, warm moist skin, myxedema, fine
resting tremor, hair loss
○ Thyroid gland is more soft and squishy than normal
Diagnosis
○ ↓ TSH
○ ↑ T3, T4
○ ↑ thyroid uptake with iodine scans
○ anti-TSH receptor Ab (activates receptor → increased production
of thyroglobulin and uptake of iodine)
Treatment
○ Methimazole, Propylthiouracil (PTU, for pregnant), radiation,
surgery
Hypothyroidism
Symptoms
○ Loss of energy, weight gain, cold intolerance,
depression, constipation
Signs
○ Delayed return phase of DTRs (most sensitive),
non-pitting edema, coarse skin, bradycardia,
hypothermia
Diagnosis
○ ↑TSH
○ ↓ T3, T4
Treatment
○ Thyroid replacement (Levothyroxine)
Pancreatic Endocrine Function
2 main endocrine functions:
○ Secrete insulin: facilitate uptake of glucose and decrease plasma glucose
○ Secrete glucagon: increases blood glucose
○ The pancreas also has exocrine functions that aid in digestion and
absorption of proteins and fats
Glucose Uptake in the
cells
❏ There are different types of glucose
transporters in each cell type
❏ Different levels of glucose sensitivity to
insulin
❏ GLUT-1 in RBC - no mitochondria,
produces lactate by glycolysis
❏ GLUT-3 In Brain- purely have glycolytic
and mitochondrial pathways but no
STORAGE capabilities
❏ Brain has limited ability to use
glycogen, proteins, fats for energy
❏ GLUT-4 in Muscle, Adipose, Liver -
glycogen pathways for converting glucose
to glycogen for energy storage
❏ GLUT-2 in Liver- dietary intake of glucose
from intestinal tract is absorbed and sent
to liver for metabolism
A closer look at how insulin is secreted….
❏ Glucose taken up into the
cell by GLUT-2 →
metabolized and
produces ATP
❏ ATP inhibits the K
channel → increases
intracellular K
concentration and
hyperpolarizes the cell →
increase uptake of Ca
❏ Ca activates insulin
transporter to secrete
insulin
A closer look at how insulin is secreted….
❏ GLP1 receptor Activated →
produces cAMP, protein kinase
A → transcription factors that
lead to production of PDX1
(increase Beta cell
mass/differentiation for the
production of more insulin on
a longer term basis
❏ Wnt pathway: AKT activating
other downstream second
messenger for the regulation
of insulin secretion
❏ PY receptors lead to insulin
reactive substrate nuclear
factor production
A closer look at how insulin works when secreted…

❏ Insulin binds to receptor →
downstream products that
lead to tyrosine kinase
activation → through
mTOR pathway,
translation initiation,
translation elongation,
lipid synthesis
❏ Regulating huge host
of enzymes in the
metabolic pathway →
gluconeogenesis, uptake
of glucose, glycogenolysis
Know pathways of carb metabolism

❏ Plasma glucose levels are the
result of a balance of these
processes
❏ Gluconeogenesis takes place in
liver and kidneys
❏ Glycolysis takes place in cytoplasm
❏ Glycogenesis takes place in liver
and muscle cells
❏ Glycogenolysis occurs in the liver
and muscle cells
Diagnostic Criteria for Diabetes
Pre-diabetes
○ Fasting BG 100-125
○ Post-prandial BG 140-199
○ Hgb A1C 5.7-6.4%
○ 40% of people with pre-DM are going to be diagnosed with DM if not controlled
with diet and lifestyle
Diabetes
○ Fasting BG > 125
○ Post-prandial >200
○ Hgb A1C>6.4%
Type I Diabetes Mellitus
Insulin DEFICIENCY so insulin DEPENDENT
Autoimmune destruction of islet cells (not making any insulin)
○ Mumps viral infection MC viral cause
Diabetic ketoacidosis (DKA)
○ Due to insulin deficiency
○ Transport of acetyl CoA into mitochondria is insulin dependent
○ If no insulin is available, Acetyl CoA is converted into ketones
Type II Diabetes Mellitus
3 things:
○ Impaired glucose uptake
○ Insulin resistance *** - the body is producing insulin but is unable to use it
properly
○ Defective insulin secretion
Genetic mutations
○ Peroxisome proliferator-activated receptor-y
○ If family history of DM, more likely for pt to develop DM
Associated with obesity- decreased adiponectin, increased leptin
Diabetic Complications
Most common complications
○ Retinopathy
○ Vascular Disease
○ Neuropathy
○ Nephropathy
Diabetics are also more prone to
infections and skin changes
Diabetic Complications
Macrovascular disease

Accelerated atherosclerosis due to lipid
dysregulation

Microvascular disease

Damaged by AGE (advanced glycosylated end
products)
Proteins bind glucose and become
glycosylated → no enzyme to “deglycosylate”
them, can only be removed by removing
protein (deposition of polyols and AGE in
intima of small vessels)
Diabetic Complications
Retinopathy

Decreased O2 delivery through microvascular disease processes
(decreased perfusion → tissue hypoxia → VEGF production → neo
proliferation in retina

Neuropathy

Small vessel ischemia or polyol deposition on myelin sheath

Causes numbness, tingling in extremities (especially the feet)

Nephropathy

Diabetic nephropathy occurs in patients with hyperglycemia from
diabetes AND a strong genetic disposition to kidney disease

Not all diabetics will get diabetic nephropathy
Infectious Disease
Know Mechanisms of Virulence
Encounter
Adherence – virus wants to stay in place long enough to propagate without being shed
Evasion of Immune System (Both innate and the adaptive)
○ Most infections are cleared by the body in healthy person
Multiplication and Spread
○ If localized to one area, limited damage
○ Damage to host is worse when infection spreads
Cell/Tissue Damage
Shedding
○ Virus will try to shed off to infect other hosts

Know that most organisms need a mode of transmission
○ They cannot survive on their own and need a host to infect others
○ Exception: fungi and anthrax bacteria which form spores
Spores have a hard shell to protect the organism inside for a long period of time
Infection Sources
Endogenous = from inside the body
○ Skin = common source of staph infections
○ Colon = FILLED with bacteria
Common source of gram (-), fungi, and anaerobe infections
○ Nose and oropharynx
Common source of staph, strep, and anaerobe infections
Exogenous = from outside the body
○ Fomites (inanimate objects that host bacteria, like a tabletop)
Listeria
E. coli
○ Animal and insect vectors
Viruses, malaria, typhus, parasites
○ Other humans
STDs
TB
Viruses
Air-borne illnesses
Mechanisms of Adherence
Viruses Bacteria
○ Adhere to and enter cells by ○ Gram (+)
receptors OR proteins on viral capsids Peptidoglycans on cell wall
○ Ex stick to cell surface
CD4 antigen for HIV ** ○ Gram (-)
Adhere to cell wall via antigens
on flagella, pili, or fimbriae
Know mechanism of adherence for HIV
Glycoprotein 120 (GP120) on viral capsid
binds to CD4 receptors on cells
This recruits chemokines by binding to CCR-5
Chemokines adhere to the virus and allow it to
penetrate and fuse to the cell membrane
Once virus has entered cell, viral replication can
occur
Know this diagram Major takeaways:

- LPS: endotoxin that
facilitates pathogenesis
of E. coli
- Fimbriae: mechanism
of adherence
- Glycocalyx: protection
from phagocytosis
- Flagella: movement
- E. coli is the most
common cause of
bladder and renal
infections
Spread and Multiplication of Organisms
Can occur by producing toxins, as seen in the Can occur by secretion of enzymes
case of ○ Streptolysin
○ E. coli, C. diff, Staph
○ Proteases
Staph creates superantigens that can
spread beyond the site of infection and ○ Lipoprotein saccharide
cause systemic disease These enzymes break down the ECM
Gram (-) organisms produce endotoxins so that bacteria can easily enter the
(lipopolysaccharides) on their outer cell walls
○ Initiates immune response with IL-1 and TNFa,
cells
causing
Fever
Permeability changes
Vasodilation
○ A-B toxins can join to create further damage
Clostridium tetani = AB toxins affect
synaptic transmission, causing muscle
spams and numbness
Vibrio cholera
Activate cAMP to open chloride
channels and cause watery diarrhea
Evasion of Host Immune Response
Inhibition of chemotaxis
○ Inhibiting chemotaxis inhibits activation of complement cascade, which is an
important part of initiating immune response
○ C5a Strep → surrounds compliment so it is not expressed or even degrades it
Killing of phagocyte
○ Α-toxin seen in Staph kills macrophages before they can engulf/destroy staph
Avoiding ingestion
○ Seen in the LPS, κ-capsule of Strep
○ K capsule prevents ingestion into endosome
Evasion of Host Immune Response
Avoiding complement lysis
○ Coating with IgA antibodies by our Neisseria gonorrhea prevents host immune
system from killing the organism by activating the MAC to avoids complement
lysis
Surviving within the phagocyte → the organism is taken into
endosome BUT prevents lysosome-endosome fusion
Survival Within Host Phagocyte
Normally, host phagocyte
destroys bacteria by
○ Bacteria binds to molecules on
cell surface (ex. TLRs)
○ Produces an evagination
endosome of cell membrane
○ Endosome buds off → enters
cytoplasm w/bacteria inside
○ Fuses w/ lysosome (contains
proteases & O2 free radicals)
○ Lysosome contents
destroy/degrade organisms
Survival within Host Phagocyte
Some organisms have created ways to evade host phagocytosis
○ Inhibition of endosome-lysosome fusion from Chlamydia
○ Inhibition of NADPH oxidase from Salmonella
○ Inhibition of H+-ATPase from tuberculosis
Inhibits acidification of endosome and this is how we get the endosome to
move into the cytoplasm to go fuse with the lysosome
Understand Antibiotic Resistance
mechanisms:
- Beta-lactamase inhibitors: that are put in penicillin to prevent the enzyme from cleaving
the beta-lactam structure of bacteria →targets the MOA of penicillin drugs, rendering them
ineffective/less effective

- Multidrug resistance transporter: Multidrug-resistant transporter = large protein
structure made up of about 10 protein subunits that span the cell membrane in the host
organism. It has cytoplasmic nucleotide-binding domain. This domain binds ATP and opens a
channel that allows a drug to be extruded from the cell. This means that the drug can not
get into the cells

- Alteration of metabolic function: Genes that alter the metabolic function of the
organism itself so the bacteria doesn’t require a certain substrate for energy or can use
another substrate

- Phage transfer: bacteria transfer certain enzymes or other component that can offer
resistance to treatment/antibiotics and survival of the organism
Know the mechanisms of how
common GI pathogens produce
disease
Which of the following is an example of fomite transmission?

A) Being bitten by a mosquito infected with Zika Virus
B) Touching a doorknob covered with adenovirus
C) Your classmate doesn’t cover their mouth when they sneeze next to
you
D) Drinking water containing giardia
Which of the following is the best example of fomite transmission?

A) Being bitten by a mosquito infected with Zika Virus- insect vector
B) Touching a doorknob covered with adenovirus- fomite vector
C) Your classmate doesn’t cover their mouth when they sneeze next to
you- indirect airborne
D) Drinking water containing giardia- indirect fecal-oral
Which of the following pathogens establishes symptomatic disease
by mechanism of bacterial colonization in the gut?

A) S. aureus
B) Salmonella
C) C. diff
D) Campylobacter
Which of the following pathogens establishes symptomatic disease
by mechanism of increased bacterial colonization in the gut?

A) S. aureus- toxin production
B) Salmonella- adhesion and mucosal invasion
C) C. diff- bacterial colonization overpowers “good bacteria”
D) Campylobacter- adhesion and mucosal invasion
Which of the following pathogens uses glycoprotein p120 as a
mechanism of adherence to infect host cells?

A) COVID-19
B) E.coli
C) Gram (-) bacteria
D) Gram (+) bacteria
E) HIV
Which of the following pathogens uses glycoprotein p120 as a
mechanism of adherence to infect host cells?

A) COVID-19- COVID spikes bind to ACE2 on host
B) E.coli- use fimbriae to attach to urothelium of the host
C) Gram (-) bacteria - adhere primarily through antigens on flagella,
fimbriae, and pili
D) Gram (+) bacteria- adhere primarily through peptidoglycan in cell
wall
E) HIV- Glycoprotein p120 on HIV virion binds to CD4 molecule
Which of the following pathogens uses opening of Cl- channels and
water secretion into the GI tract as a mechanism of pathogenesis?

A) Vibrio Cholera
B) E. Coli
C) C. tetani
D) Staph a.
Which of the following pathogens uses opening of Cl- channels
and water secretion into the GI tract as a mechanism of
pathogenesis?
A) Vibrio Cholera- Uses toxin to cause opening of Cl-channels
resulting in excess water into GI tract causing “rice water
diarrhea”
B) E. Coli- Uses LPS endotoxin to produce inflammation
C) C. tetani- Uses neurotoxin to cause inhibit the release of
neurotransmitter and cause paralysis
D) Staph a.- Uses superantigen to initiate exaggerated immune
response
Which of the following pathogens utilizes an IgA antibody coating to
protect from complement-induced lysis?

A) Strep
B) Neisseria
C) Chlamydia
D) TB
Which of the following pathogens utilizes an IgA antibody coating to
protect from complement-induced lysis?

A) Strep
B) Neisseria- IgA antibody protects from initiation of
complement
C) Chlamydia
D) TB

*** IgA does not activate complement → coating in IgA prevents
complement lysis
Which of the following HPV subtypes are most closely associated with
cervical cancer?

A) 6 & 11
B) 31 & 33
C) 16 & 18
D) 35 & 39
Which of the following HPV subtypes are most closely associated with
cervical cancer?

A) 6 & 11- most commonly associated with genital warts
B) 31 & 33- associated with cervical cancer, but not as frequently
C) 16 & 18- most commonly associated with cervical cancers
D) 35 & 39- associated with cervical cancer, but not as frequently
Which of the following mutations is associated with the development of
cervical carcinomas?

A) Inhibition of p53 gene
B) Inhibition of PTEN gene
C) Upregulation of EGFR gene
D) Upregulation of RB gene
Which of the following mutations is associated with the development of
cervical carcinomas?

A) Inhibition of p53 gene- decrease activity of this tumor
suppressor gene results in increase cervical carcinoma
B) Inhibition of PTEN gene- decrease activity of this tumor suppressor
gene results in increase of breast and colon cancer
C) Upregulation of EGFR gene- upregulation of this proto-oncogene
results in increase of colon cancer
D) Upregulation of RB gene- upregulation of tumor suppressor gene is
protective against the development of cervical cancer

*** inhibition of RB would result in an increase in in cervical cancer
Know the common HIV/AIDS-related
illnesses
Thank you!
Questions? Email me ([email protected])