Exam 3 Terms & Concepts PDF

Summary

These notes cover key concepts in neurology, such as the function of neurons and neuroglia, metabolic requirements of nervous tissue, and different types of pain. The document also touches upon the gate control theory of pain and differentiates between various types of pain.

Full Transcript

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Lecture Topic Ch. # Exam Blueprint

10/28 Neuro 13-16

11/4 Integumentary & Burns 51 & 52

11/4 Musculoskeletal 47-50

11/11 Endocrine & DM 40 & 41

11/18 Renal & GU 32-35

11/21 EXAM 3

Notes by Objective:

Neuro:

Distinguish b/w functions of the neurons & neuroglial cells of the nervous system.
Nervous tissue contains 2 types of cells:
○ neurons → fundamental unit of the neurological system
exhibit excitability & conduct impulses
afferent = sensory → send info to CNS
efferent = motor → carry info away from CNS
gray matter is mostly neuronal cell bodies
○ neuroglial cells → create the scaffolding
protections & support, glycogen storage
astrocytes form the BBB
oligodendrocytes & Schwann cells produce myelin →
increase velocity of nerve impulses
white matter is mostly glial cells & myelinated axons (myelin has a high lipid content,
hence the whitish color)
Components of neurons: know what parts send signals and receive signals
○ Dendrites → have receptors for NT binding, RECEIVE signals
○ Cell body (soma) → RECEIVE signals
○ Axon → SEND signals
○ Axon terminals → release NTs
Explain the metabolic requirements of nervous tissue.
Brain receives 15%-20% of the total resting CO & consumes 20% of its oxygen → LARGE energy
requirements
No way of storing oxygen → vulnerable to hypoxia → results in a rapid onset of clinical signs:
○ AMS/confusion/restlessness
○ lethargic or combative
○ loss of consciousness → occurs almost simultaneously w/ cardiac arrest
cell death begins within 4-6 mins
○ seizure activity
Main energy source = glucose
○ small glycogen stores within supporting neuroglial cells
○ brain still vulnerable & sensitive to hypoglycemia → checking BS is protocol in an AMS pt

Summarize the gate control theory of pain.
experience of pain is modulated by a “gate” mechanism in the spinal cord; there are two proposed
pathways:
○ descending (efferent) pathways interfere w/ ascending (afferent) pain signals → can either
amplify or inhibit
cognitive or emotional factors
“mind over matter”
i.e. benefit of meditation, monks
○ ascending (afferent) signals from peripheral nerves COMPETE
large-diameter A-beta fibers (associated w/ non-nociceptive input, like touch) are
faster & activate inhibitory interneurons in the dorsal horn that “close” the gate on
pain transmission
rubbing, massage, vibration, TENS
○ Transcutaneous electrical nerve stimulation (TENS) uses low-voltage
electrical currents to relieve pain. A TENS unit is a small device that
delivers the current at or near your nerves to block or change your
perception of pain
small-diameter A-delta (associated w/ nociceptive input, like pain) are excitatory &
contribute to pain transmission

Differentiate b/w neuropathic pain, neuralgias, and phantom limb pain.
Types of pain:
 ○ cutaneous → arises from superficial structures, sharp, burning qualities (scrape, burn,
cellulitis)
○ deep somatic → originates in deep body structures (ischemia, sprained ankle)
○ visceral → originates from internal organs (contractions, distention, ischemia); diffuse @ 1st &
can later become localized (appendicitis)
○ referred → pain perceived at a different site than its point of origin but innervated by the same
spinal segment → be familiar with the concept of dermatomes
neuropathic pain → BROAD category of nerve-related pain; refers to a stimulus stemming directly
from neuronal cells, versus non-neuronal tissue, due to some kind of damage to the nerve
○ peripheral nerve damage in a single area:
nerve entrapment
nerve compression
tumor mass
neuralgias
○ peripheral nerve damage in a wide area:
diabetes mellitus
long-term alcohol-use
hypothyroidism
amputation → phantom limb pains
○ CNS lesion/dysfunction
neuralgia → symptom of neuropathy; characterized by severe, brief, often repetitive attacks of
lightening-like or throbbing pain
○ trigeminal neuralgia
○ postherpetic neuralgia (i.e. shingles)
○ phantom limb pain → results from a mismatch b/w the brain’s “map” of the body and sensory
input; the brain continues to send signals to the area where the limb used to be, and without
feedback from the missing limb, it can create pain sensations as part of the adaptive response

Discuss alterations in structure or function, risk factors, clinical manifestations, and
selected treatments for the following conditions:
Skeletal Muscle Disorders:
○ Muscular dystrophy → genetic disorders that produce progressive deterioration of skeletal
muscle bc of mixed muscle cell hypertrophy, atrophy, & necrosis
most common type: Duchenne’s or DMD
as muscle undergoes necrosis, fat & CT replace muscle fibers (pseudohypertrophy) →
increases muscle size & results in muscle weakness
insidious in onset but continually progressive
clinical manifestations:
 frequent falling → evident at 2-3 years of age
pseudohypertrophy of calf muscles
imbalances b/w agonist & antagonist muscles → abnormal posture,
contractures & joint immobility; scoliosis is common
respiratory muscle involvement → breathing problems
cardiac muscle involvement → cardiomyopathy
Disorders of the Neuromuscular Junction (NMJ)
○ Myasthenia gravis (“grave weakness”) → autoimmune disease; antibody-mediated attack on
acetylcholine receptors in the NMJ → leads to fewer receptors on post-synaptic cleft &
impaired signal transmission
acetylcholine = NT that triggers muscle contraction; enables voluntary muscle
movements & helps regulate involuntary functions (i.e. HR & digestion)
clinical manifestations:
ptosis d/t eyelid weakness
diplopia d/t extraocular muscle weakness
chewing & swallowing difficulty (dysphagia)
slurred speech
predisposition to rapid fatigue
symptoms worse in the afternoon, evening
Peripheral Nerve Disorders:
○ Guillain-Barre → acute autoimmune attack on myelin sheath; lower motor neuron disorder
most people report having an acute, influenza-like illness before the onset of
symptoms
clinical manifestations:
progressive ascending muscle weakness of the limbs → symmetric flaccid
paralysis
paresthesia & numbness
respiratory muscle paralysis → ventilator required
severity & duration can range from mild weakness w/ spontaneous recovery
to developing tetraplegic & ventilator dependence w/ no signs of recovery for
several months or longer
ascending GBS a lot more common than descending GBS
cervical 3,4,5 keep the patient alive
Disorders of the Basal Ganglia:
○ Parkinson's disease → degenerative disorder caused by destruction of dopaminergic neuronal
cells in the substantia nigra in the basal ganglia; results in an imbalance b/w dopamine & ACh
dopamine = allows for controlled movement & suppression of involuntary or
unnecessary motor activity
acetylcholine = excitatory neurotransmitter
 in Parkinson's → too little dopamine, unopposed acetylcholine
risk factors:
genetic linkage
TBI
antipsychotic drug use
CO poisoning
diagnostic:
Lewy bodies
clinical manifestations:
tremors → rhythmic, alternating flexion & contraction movements, “rolling a
pill” w/ thumb & forefinger
○ occurs at rest, disappears w/ movement & sleep
○ initially unilateral; progresses bilaterally
rigidity → reduced ROM, flexion contractions
bradykinesia → slowness in initiating & performing movements & difficulty
w/ sudden, unexpected stopping of voluntary movements
○ akinesia → complete absence of movement
loss of postural reflexes → shuffling gait, “crouched” stance, predisposition to
falling
treatment:
replace dopamine → levodopa (precursor to dopamine)
restore DA/ACh balance → anticholinergic drugs (i.e. benztropine)
Upper Motor Neuron Disorders:
○ Amyotrophic lateral sclerosis (Lou Gehrig’s disease) → debilitating autoimmune disorder;
both UMNs (in the brain) & LMNs (in spinal cord & brainstem) degenerate → breakdown of
NMJs, preventing effective communication b/w nerves & muscles
loss of motor neurons disrupts voluntary muscle control → leads to progressive
muscle weakness, paralysis, & eventual death (usually within 3 years)
sensory & cognitive functions are usually preserved
clinical manifestations:
muscle weakness & atrophy
○ most common = slowly progressive weakness & atrophy in distal
muscles of one upper extremity
spasticity & hyperreflexia
difficulty speaking & swallowing
respiratory compromise
○ Multiple sclerosis → chronic autoimmune disease that affects the CNS, leading to progressive
damage of the myelin sheath → demyelination process leaves scar tissue, or “sclerosis/plaques,”
at multiple sites → over time, attacks lead to axon loss & permanent/irreversible nerve damage
 clinical manifestations:
muscle weakness, spasticity, & gait difficulties; reduced mobility over time
numbness, tingling, & neuropathic pain
vision & hearing loss
memory issues, attention deficits, executive function difficulties, emotional &
mood dysregulation
FATIGUE
bowel & bladder dysfunction
complications:
paralysis of legs
epilepsy
depression
treatment:
slow damage → corticosteroids & interferons
symptoms management → antidepressants, anticholinergics, laxatives

Differentiate b/w epidural, subdural, and intracerebral bleeds.
epidural → b/w skull & outermost membrane layer (dura)
○ head trauma → briefly knocked unconscious → full return
to lucidity → hematoma grows & is followed by rapid loss
of consciousness for the 2nd time
○ associated with arterial bleeding d/t skull fractures
○ manifestations:
focal symptoms
ipsilateral pupil dilation
contralateral hemiparesis
○ prognosis: excellent if hematoma removed before 2nd loss
of consciousness
subdural → b/w dura mater & arachnoid
○ vein tear or rupture → develops more slowly, depending
on the extent of tear
acute → progresses rapidly
subacute → s/s within days or weeks after injury
chronic → s/s take weeks & months to appear
○ higher mortality rate d/t severe secondary injuries related to edema & increased ICP
intracerebral → occurring in lobes, brainstem, cerebellum
○ etiology: hemorrhagic stroke, head injury, aneurysm, tumor, HTN
 ○ think stroke symptoms:
confusion
headache
slurred speech
loss of movement (paralysis) on opposite side of the body from the head injury

Major areas of the brain = LOBES
○ frontal → voluntary motor, personality, executive function
prefrontal cortex
primary motor cortex
○ parietal → processes sensory information related to touch, temperature, pain, & spatial
awareness, hand-eye coordination
somatosensory cortex
○ occipital → visual processing, object recognition
primary visual cortex
○ temporal → hearing, smell, memory
primary auditory cortex
hippocampus

Compare and contrast ischemic & hemorrhagic stroke.
ischemic → obstruction of oxygen delivery d/t a clot
○ ischemic band of cells (the ones dying d/t a lack of O2 & glucose) = penumbra
○ thrombotic → atherosclerotic blood vessels
○ cardiogenic embolic → vegetation (endocarditis), plaque breakage, clot formation (afib);
essentially moving clot
○ transient ischemic attack (TIA) → have multiples, precursor to actual stroke, no permanent
damage
○ Treatment:
supplemental, high-flow O2
diagnose → CT to rule out hemorrhagic
clot buster → TPA
hemorrhagic → disruption of oxygen delivery d/t ruptured artery, usually fatal
○ hard to recognize early enough to remedy
○ pt experiences headache (“worst headache of my life”) & n/v → contralateral hemiplegia w/
initial flaccidity → progresses to spasticity
○ Risk factors:
anticoagulant-use
HTN
 structural abnormality (i.e. previous aneurysm → weakening of arterial wall)
General stroke risk factors:
○ diabetes
○ smoking
○ a-fib
○ hyperlipidemia
○ CAD
○ coagulation disorders
○ heavy alcohol use

Describe alterations in structure, risk factors, and clinical manifestations of
subarachnoid hemorrhage & cerebral aneurysm.
subarachnoid hemorrhage → most commonly caused by rupture of cerebral aneurysm (also caused by
trauma & arteriovenous malformations (AV malformation))
○ AV malformations:

tangle of blood vessels → arteries & veins are directly connected w/o capillaries →
high-pressure, fast-flow system
thin walls of veins are vulnerable to arterial pressure → they stretch, weaken, &
become prone to rupture
○ complications:
increase in ICP
disruption of CSF flow
○ clinical manifestations:
before rupture → atypical headache
after rupture → “worst headache of my life” → photophobia → vomiting → nuchal
rigidity → collapse/loss of consciousness
cerebral aneurysm → bulge/ballooning at site of localized weakness of arterial wall
Describe the etiology, diagnosis, and treatment of seizures.
abnormal, excessive nerve-firing
prodromal → aura → ictus → post-ictus
Generalized: entire brain is affected
○ tonic-clonic:
may begin with an aura
initial stiffening (tonic) stage → pt falls and muscle tenses up (10-30 seconds)
clonic stage → uncontrolled convulsions (30-60 seconds)
post-seizure phase → confusion & muscle aches
○ myoclonic: sudden jerking or stiffening of the extremities
○ absence: blank stare, “spacing out,” more common in children, looks like daydreaming, no
recovery period
○ atonic: “drop attacks”
Partial/focal: one area of the brain is affected
○ simple partial:
consciousness & awareness are preserved
○ complex partial
consciousness & awareness is impaired

Integumentary & Burns

Correlate the pathophysiology of burn injury to the major complications.
Types of burns:
○ thermal → scald & flame; fire, hot liquid, or steam
○ chemical → industrial agents; strong acids, alkalis, or corrosive substances
○ electrical → usually more extensive d/t internal tissue injury & presence of entrance & exit
wounds
○ radiation → typically from exposure to UV light or radiation therapy
effects of UVA & UVB (sunburn rays) → short-lived & reversible
erythema
pigmentation
injury to Langerhans cells & keratinocytes (in epidermis) → weakens skin’s
protective functions
○ Langerhans cells: APCs, activation of innate immune response
○ Keratinocytes: produces protective protein that strengthens skin,
release cytokines that help regulate immune response
Depths of burns:
Class 1st-Degree burns 2nd-Degree burns 3rd/4th-Degree Burns

Depth Superficial Partial-thickness Full thickness

Layers affected only epidermis epidermis & part of extends through all skin
dermis layers

clinical red, dry, painful w/o redness, blistering (shiny, dry, waxy white, leathery,
manifestations blisters wet), swelling, severe hard skin, no pain
pain

nursing requires hospitalization requires immediate
considerations if > 25% of BSA hospitalization

examples sunburn tar burn, flame exposure to flames,
electricity or chemicals

Local response:
○ inflammatory → release of histamines, bradykinin, & cytokines → vasodilation & ↑ capillary
permeability
○ fluid shift → proteins & fluids leak into surrounding tissues → edema
○ nerve damage & pain
Systemic response: (first 24 hours)
 ○ Cardiovascular → hypovolemia from massive fluid shift → ↓ CO → reflex tachycardia to
compensate → high risk of shock
epinephrine secreted to induce vasoconstriction → shunts blood to vital organs
○ Renal → baroreceptors trigger compensatory mechanisms
UO decreases → causes by convervation effort or lack of renal perfusion
RAAS system → ADH & aldosterone secretion → effort to retain Na+ & H2O
○ Respiratory → inhalation injuries can result in airway edema
**maintaining airway patency is priority nursing intervention here
○ Immune → loss of protective skin barrier exposes body to pathogens → high risk for infection
& sepsis
○ Metabolic → increased energy needs to support wound healing & recovery → can lead to
catabolism
pts put on high-calorie, high-protein diets
Major Complications:
○ Hypovolemic shock
Priority nursing intervention: FLUID REPLACEMENT
albumin given to maintain vascular tone
Fluid volume assessment: urine output
Kidney perfusion assessment: GFR (90-120 mL/min)

Calculate the total body surface area affected by a burn using the rule of 9s.
A patient has sustained partial-thickness burns on their entire right arm and the anterior portion of their
right leg.
○ entire right arm: 9%
○ anterior RT leg: 9%
A patient presents with burns on the anterior trunk and both anterior thighs.
○ anterior trunk: 18%
○ both anterior thighs: 9%
A patient has sustained third-degree burns to the entire anterior and posterior right arm, the entire anterior
chest and abdomen, and perineal area.
○ entire RT arm: 9%
○ entire anterior chest: 9%
○ anterior abdomen: 9%
○ perineal area: 1%
Musculoskeletal

State the function of parathyroid hormone, calcitonin, and vitamin D in terms of bone
formation and metabolism.
Parathyroid hormone (PTH): released by parathyroid glands in response to low blood Ca2+ levels
○ stimulates osteoCLAST activity → break down of bone to increase Ca2+ levels in blood
Calcitonin: produced by thyroid gland when blood Ca2+ levels are high
○ inhibits osteoclast & stimulates osteoBLAST activity → bones absorb Ca2+ from blood
stream to decreases levels in the blood
Vitamin D (Calcitriol): increases calcium absorption in the intestines

Differentiate between contusion, hematoma, and laceration.
Contusion: injury to soft tissue that results from direct trauma
Hematoma: large area of local hemorrhage
Laceration: skin is torn or its continuity disrupted

Compare and contrast the traumatic musculoskeletal injuries.
Fractures: a break in continuity of a bone
○ could be caused by direct blow/impact, crushing forces, extreme muscle contractions
○ could also be secondary to an underlying condition: osteoporosis, osteomyelitis, tumor,
infection, metabolic bone disorders → “pathological fx”
○ s/s: pain, swelling, deformity, impaired function, impaired sensation, muscle spasm
○ TYPES
complete v. incomplete
open v. closed → dependent on soft tissue involvement
greenstick: seen among children
directions: linear, oblique, spiral, transverse, comminuted
pathologic/spontaneous
a fall of a pt with osteoporosis can lead to snapping the head of the femur
bone
other secondary causes: tumor, osteomyelitis
Dislocations: joint moved out of its normal position
Strains: tear or injury to TENDON
Sprains: tear or injury to LIGAMENT–Type III is a complete severing of a ligament
Examine complications of musculoskeletal injuries to include compartment syndrome,
venous thromboembolism, and fat embolism.
Compartment syndrome: increased pressure within limited space that compromises circulation and
function of tissues within the space
○ can cause permanent nerve damage and possibly loss of limb
○ treatment: cut into the space to relieve pressure & restore circulation — fasciotomy
○ etiology: trauma, swelling, vascular injury, venous obstruction
○ s/s: pain, pulselessness, paresthesia, polar, paralysis, pallor
Venous thromboembolism:
○ Virchow’s Triad:
venous stasis, immobilization
vessel wall injury
hyper-coagulability
Fat embolism: fat cells within bone can be released when fracture and effectively become a traveling
clot

Trace the mechanism of Osteomalacia.
bones that are being made are very weak — inadequate mineralized bone matrix
kidneys are responsible for metabolizing Vitamin D & converting it to active form, calcitriol
Causes:
○ dietary deficiency in vitamin D, calcium, or phosphorus
○ deficient vitamin D metabolism — lowers absorption of calcium from intestines
○ renal tubular phosphate loss (hereditary) → decreased resorption of phosphate
Treatment: oral supplements
vitamin D- deficiency is a greater risk for kids who were breast fed
Foods high in Ca2+:
○ dairy products
○ green leafy vegetables
○ fortified foods → OJ, plant-based milks, cereals
○ nuts & seeds
○ tofu
Foods high in phosphorus:
○ meat, fish, eggs
○ dairy products
○ whole grains
○ potatoes
○ nuts & seeds
Summarize alterations in structure or function, risk factors, clinical manifestations, and
treatments for the following musculoskeletal disorders:
Osteomyelitis: damage to the bone + opportunistic pathogen
Osteoporosis: reduced bone mineral density, imbalance in bone formation (clast>blast)
○ risk factors: sex, advancing age, body size, race, family hx, changes to hormones, diet, long-term use
of certain meds (glucocorticoids…), drinking, smoking, inactivity
low estrogen levels in women after menopause
low levels of testosterone men
Paget disease: chronic condition of bone turnover characterized by disorder of normal bone remodeling
process
○ excessive breakdown of bone tissue (overly active clast activity), followed by abnormal bone
formation (dysfunctional blast activity)
○ normal bone marrow is replaced by vascular, fibrous, connective tissue that leads to formation of
larger, disorganized, & weaker bone tissue
Rheumatoid arthritis: autoimmune disease
○ the more they move around, the better it is for long-term mobility
Osteoarthritis: age-related, degenerative joint disease
Gout: build up of uric acid levels in the body, high serum level > 8.5 mg/dL
○ foods high in purines → red meat/organ meats, seafood, alcohol, sugary drinks, high fructose corn
syrup

Endocrine:

Identify the source and major action of the following hormones:
Hypothalamus: ‘R’ = releasing
CRH
TRH
GHRH
Somatostatin: inhibits GH & TSH
Pituitary gland:
GH: stimulates growth of the bone & muscle,
promotes protein synthesis & fat metabolism,
decreases carbohydrate metabolism
ACTH: stimulates synthesis & secretion of
adrenal cortical hormones
TSH: stimulates synthesis & secretion of thyroid
hormone
ADH: ↑ H2O reabsorption by kidneys
Adrenal Cortex:
Aldosterone: ↑ Na+ reabsorption & K+ loss by
kidneys (indirectly promoting water retention)
Cortisol: affects metabolism of all nutrients; regulates
blood glucose levels, affects growth, has
anti-inflammatory action, & decreases effects of stress
(in the short-term)
Androgens
Adrenal Medulla: SNS NTs
Epinephrine
Norepinephrine
Thyroid:
Thyroid hormone: increases metabolic rate; necessary
for fetal & infant growth & development
Calcitonin: ↓ Ca2+ & phosphate levels in the blood
Parathyroid:
PTH: ↑ Ca2+ & phosphate levels in the blood
Pancreas:
Insulin: ↓ blood glucose; facilitates glucose transport
across cell membranes
Glucagon: ↑ blood glucose; stimulates glycogenolysis & glyconeogenesis

Describe the role of the hypothalamus and pituitary gland in regulating pituitary
control of endocrine function.
hypothalamus → centrally located in the brain → COORDINATING CENTER
○ receives neural input r/t emotion, pain, body temperature…& communicates to the rest of the
endocrine system via hormonal cascade
○ releases “releasing” or “inhibiting” hormones
pituitary gland (aka hypophysis) → connected to the floor of the hypothalamus → MASTER GLAND
○ directly communicates with the ‘coordinating center’ by blood & nerves
○ its hormones control the functions of many target glands & cells
○ anterior pituitary → TSH, ACTH, GH
○ posterior pituitary → ADH
Identify the role of growth hormone including consequences of hypo- or hyper-secretive
states.
Growth Hormone (GH) → necessary for growth & contributes to the regulation of metabolic
functions
○ cartilage growth
○ linear bone growth → direct action on the epiphyseal growth plates
○ increased protein synthesis → lean muscle mass development
○ increased size and function of body organs
GH deficiency → endocrine disorder leading to short stature pituitary Dwarfism
○ ↑ subcutaneous fat in the abdominal area
○ immature facial features
○ delayed dentition
○ underdeveloped nasal bridge
○ ↓ BMD & lean muscle mass
GH excess → endocrine disorder leading to tall stature, or pituitary Gigantism
○ when this occurs in adulthood, after the epiphyses of long bones have fused, the condition is
referred to as acromegaly
○ in children → excessive skeletal growth & tall stature
○ in adults:
enlargement of small bones of hands & feet
broad & bulbous nose
protruding jaw
slanting forehead
cartilaginous structures become enlarged (larynx & respiratory tract)
enlargement of virtually every organ → ex. development of HTN d/t cardiomegaly

Discuss alterations in structure or function, identify compensatory mechanisms, clinical
manifestations, risk factors, and treatments for:
Thyroid hormone (TH) → increases metabolism & protein synthesis & is necessary for growth &
development
○ Metabolic rate:
lipids are mobilized from adipose tissue
catabolism of cholesterol by liver
increased absorption of glucose from GI tract
○ Cardiovascular fxn:
↑ O2 consumption (d/t increased metabolic rate)
 ↑ vasodilation, blood volume, CO, & ventilation
enhanced HR & contractility w/o a rise in BP (vasodilation offsets ↑ CO)
○ Gastrointestinal fxn:
↑ motility & gastric secretions
↑ appetite
weight loss

Thyroid [TRH → TSH → T4 & T3]

Hypothyroidism: deficient Hyperthyroidism: excessive
production of TH production of TH

General behavior mental & physical sluggishness, restlessness, irritability, anxiety, fine
somnolence tremors

Cardiovascular ↓ CO, bradycardia ↑ CO, tachycardia, palpitations

GI constipation, decreased appetite diarrhea, increased appetite

Temperature tolerance cold intolerance heat intolerance

Skin & hair decreased sweating; coarse & dry skin increased sweating; thin & silky,
& hair velvety skin & hair

General features myxedematous features (generalized exophthalmos (in Graves disease)
puffiness)

Acute State Myxedema coma Thyroid storm

Causes of primary: thyroidectomy Grave’s disease
(destruction or dysfunction iodine deficiency → Goiter adenoma of the thyroid
of thyroid gland) development thyroiditis
Hashimoto’s
radiation

Treatment lifetime, levothyroxine high-calorie diet
low-calorie beta-blockers
radiation
***let’s think about primary and secondary causes together
Goiters → can occur in hypo-, eu-, or hyper-thyroid states
○ NURSING CONSIDERATION: dysphagia & respiratory status
 Adrenal Cortical Hormones → aldosterone (mineralcorticoid) & cortisol (glucocorticoid)
○ Aldosterone (RAAS & K+ levels) → regulate K+ & Na+ levels and water balance
○ Cortisol (CRH → ACTH → cortisol) → glucose metabolism, protein metabolism, fat
metabolism, anti-inflammatory action

Adrenal Cortical
Addison Disease: AC insufficiency Cushing Disease: hypercortisolism

hyperpigmentation, hypotension, buffalo “hump,” “moon face,” truncal
hypoglycemia, poor tolerance to stress, obesity, abdominal striae, amenorrhea,
fatigue, anorexia, GI upset, polyuria osteoporosis, HTN, HF,
w/retention of K+ hyperglycemia, Na+ retention &
hypokalemia, “roid rage”

Priorities ↑ K+ levels → cardiac arrhythmias → ↓ Ca2+ absorption, ↑ risk of infection,
elevated T-waves; fluid volume deficit fluid volume overload

Causes tumors of adrenal gland
small cell lung carcinoma
secreting ACTH or CRH
iatrogenic

Treatment “Add a -sone” → surgery
hydrocortisone or irradiation
fludrocortisone pharmacological therapy
↑ Na+ in diet

Acute crisis Addisonian crisis → triggered by
minor illness or stress
DM:

Contrast the hormones glucagon & insulin.
Insulin → promotes cellular uptake of glucose & storage of glucose as glycogen or fat → pulls from
circulation → lowers blood sugar
○ inhibits lipolysis
Glucagon → stimulates gluconeogenesis (creates more glucose from glycogen stores in the liver) →
glucose released into circulation → raises blood sugar

Metabolism = balance b/w anabolism & catabolism

Discuss alterations in structure or function, identify compensatory mechanisms, clinical
manifestations, risk factors, and treatments for the following key abnormal conditions:
DM 1:
○ considered autoimmune → targeted destruction of pancreatic beta cells → absolute insulin
deficiency
○ often r/t a genetic predisposition
○ insulin-dependent; childhood onset
DM II:
○ majority of cases of DM (90-95%)
○ heterogenous; lifestyle-dependent → overweight/obese, sedentary, smoking, high-fat diet; there
is also a strong genetic component
○ insulin-resistant, deranged secretion of insulin, increased glucose production by the liver
can have high, normal, or low insulin levels; type II is simply characterized by the
decreased ability of insulin to act effectively on target tissues
Metabolic Syndrome: constellation of abnormalities caused by insulin resistance
○ visceral obesity
○ high levels of triglycerides
○ low levels of HDLs
○ HTN
○ systemic inflammation (indicated by ↑ CRP)

Discuss the acute complications of diabetes mellitus.
hypoglycemia:
○ headache, difficulty problem solving, coma, seizures, anxiety, tachycardia, sweating, &
constriction of blood vessels (PALE, COOL, CLAMMY)
○ 15g carbohydrate snack or oral glucose tab, recheck blood glucose in 15 mins
 ○ if pt is unconscious → glucagon 1 mg IM or subcut, then have them ingest complex carb after
recovery (sweet potatoes, oatmeal, or whole grain bread)
○ important to know that this state can mimic alcohol intoxication

Contrast DKA & r:

DKA (greater association w/ DM I) HHS (greater association w/ DM II)

rapid onset ( 300 > 600

Differentiating hyperglycemia, ketones present in urine hyperglycemia, hyperosmolarity,
manifestations & blood, GI upset (metabolic acidosis), dehydration, seizures, reversible paralysis
fruity breath, Kussmaul’s

Both polyuria, polydipsia, polyphagia, weight loss, blurred vision, headache, weakness,
orthostatic hypotension, mental status changes

Treatment correct fluid/electrolyte imbalance; when similar to DKA, yet greater focus on
blood glucose approaches 250, D5W is fluid administration
added to fluid therapy, insulin drip

Considerations watch that potassium level

Discuss the chronic complications of DM.
Microvascular:
○ neuropathy
○ retinopathy
○ nephropathy
Macrovascular:
○ CAD
○ peripheral vascular disease
○ diabetic foot ulcers
○ infections
Renal & Genitourinary:

Review Starling Forces
*related to how fluid moves into & out of tissues, how the kidneys are absorbing & getting rid of fluid…
Starling/Pressure forces:
○ hydrostatic → pressure that pushes fluid away
capillary hydrostatic: dependent on arterial & venous blood pressure (factors that ↑
BP, will also ↑ hydrostatic pressure)
interstitial hydrostatic: dependent on tissue &
lymphatic drainage efficiency
opposes filtration if +
promotes filtration if -
○ oncotic/osmotic → pressure that pulls fluid towards
plasma oncotic: dependent on osmotically
active particles in the blood
Main contributor = albumin = most
abundant plasma protein & is given as
an IV colloid solution to expand blood
volume
promotes reabsorption
interstitial oncotic: dependent on protein leakage into the interstitium or tissue injury
promotes filtration
Colloid: a mixture where tiny particles are dispersed throughout a continuous medium
○ milk
○ detergent
○ blood
○ smoke
FLUID SHIFTS: it’s all about the net filtration pressure (NFP)
○ plasma → interstitial
examples:
Edema in HF: ↑ capillary hydrostatic pressure d/t elevated venous pressure
Localized edema w/inlammation or injury: ↑ capillary permeability d/t
inflammatory mediators like histamine
Hypoalbuminemia w/liver disease or malnutrition: ↓ capillary oncotic
pressure d/t low plasma protein levels
○ interstitial → plasma
examples:
 Albumin infusion for hypovolemia: ↑ plasma oncotic pressure d/t exogenous
albumin administration (important treatment for burns to restore circulating
volume)
Use of diuretics for edema: ↓ capillary hydrostatic pressure as excess fluid is
removed from circulation
Osmotic diuretic (mannitol) administration for ↑ ICP: increases plasma
osmolarity, drawing H2O into vascular space, but prevents water
reabsorption in the renal tubules, promoting diuresis

Discuss alterations in structure or function, risk factors, clinical manifestations, and
selected treatments for the following conditions:
Renal Calculi/Nephrolithiasis (“kidney stones”):
○ most common cause of upper urinary tract obstruction
○ Contributing factors:
supersaturated urine w/ stone components:
calcium salts
○ hypercalcemia
○ high doses of Vitamin D
○ immobilization
○ hyperparathyroidism
○ intestinal bypass surgery
struvite (magnesium ammonium phosphate)
○ UTIs
uric acid
○ gout
○ high protein diet
○ diabetes
○ metabolic syndrome
○ chronic diarrhea or
malabsorption
cystine (amino acid)
○ hereditary disorder
○ Clinical manifestations:
PAIN
acute, intermittent, & excruciating in
the flank & upper outer quadrant of
the abdomen on affected side; can
radiate to lower abdomen
 deep, dull ache in the flank or back
exaggerated by drinking large amounts of fluid
hematuria
nausea/vomiting
fever and chills if infection accompanies obstruction
○ Treatments:
fluids, pain management
medications:
tamsulosin → relax ureteral muscles
dutasteride & tamsulosin
procedures/surgeries
prevention?
Urinary Tract Infections
○ bacterial infection of the urinary tract, usually caused by E. coli
○ affects the bladder (cystitis) or urethra, w/ potential progression to the kidneys (pyelonephritis)
○ Risk factors:
female anatomy (shorter urethra), menopause d/t pH changes
sexual activity (recommend peeing after intercourse)
catheterization, urinary retention, or structural abnormalities
blockages–kidney stones or enlarged prostate
diabetes or immunosuppression
○ Clinical manifestations: look at the difference based on location
dysuria (painful urination), urinary frequency/urgency
suprapubic pain or pressure
cloudy, malodorous urine
fever & systemic symptoms if infection progresses
○ Treatment:
short-course or broad-spectrum abx → need to finish complete course
evaluation for structural issues
prevention: adequate hydration, post-coidal voiding, & cranberry supplementation
Glomerulonephritis:
○ inflammation of the glomeruli, impairing filtration
○ leads to proteinuria, hematuria, azotemia, reduced GFR, oliguria, HTN, & potential kidney
failure
○ can be acute or chronic
○ Risk factors:
infection
autoimmune diseases (SLE, DM…)
○ Clinical manifestations:
 hematuria (cola-colored urine) & proteinuria
edema (periorbital, lower extremities)
HTN
fatigue & oliguria (no urine production)
azotemia → waste products & toxins remain in circulation & can accumulate
○ Treatment:
acute → symptomatic support
chronic → scarring → given dialysis to remove toxins
medications:
ACE inhibitors → reduce pressure/blood flow through kidneys
corticosteroids → reduces inflammation & scarring
Pyelonephritis (aka upper UTI):
○ infection of the renal parenchyma and pelvis, typically ascending from the lower urinary tract

○
○ Risk factors:
untreated or recurrent UTI (apply the same risk factors)
○ Clinical manifestations:
chronic or severe → reduced concentrating ability → more dilute urine = low specific
gravity

Differentiate between acute kidney injury (AKI) and chronic kidney disease (CKD).
Kidney Labs: (Cr/BUN increase when kidneys are stressed; GFR decreases)
Creatinine
○ normal range: 0.6-1.2 mg/dL
○ waste product of muscle metabolism; freely filtered in the glomeruli
Blood urea nitrogen (BUN)
○ normal range: 8-20 mg/dL
○ urea is the end product of protein metabolism
 ○ influenced by protein intake, GI bleeding, & hydration status (if BUN is high, but Cr is normal
→ indicates another issue like dehydration)
○ approximately ⅔ of renal function must be lost before a significant rise in BUN level occurs
eGFR (estimated glomerular filtration rate)
○ measured clinically using mathematical formula
○ measures kidney function
○ decreases with kidney disease & age
○ normal range: 90-120 mL/min

Acute Renal Failure/Acute Kidney Injury (ARF/AKI): abrupt loss of kidney function (over hours or
days)
○ reduced GFR, accumulation of nitrogenous waste products (creatinine & urea), &
disturbances in fluid, electrolyte, and acid-base balance
○ typically reversible w/timely intervention
○ Causes:
prerenal: decreased perfusion–hypovolemia, HF, sepsis
intrarenal: damage to kidneys–acute tubular necrosis, glomerulonephritis
acute tubular necrosis = most common cause → destruction of tubular
epithelial cells d/t nephrotoxic drugs or low BP
postrenal: obstruction–stones, tumors, enlarged prostate
○ Stages:
oliguric → fluid and waste retention/accumulation; reduced GFR
uremic symptoms: n/v, confusion, fatigue
hyperkalemia, metabolic acidosis
diuretic → gradual increase in UO; often exceeding 3-5 L/day; increased GFR
polyuria; risk of hypovolemia & dehydration
hypokalemia & hyponatremia
recovery → return to normal or near-normal renal function
can take months
Chronic Kidney Disease (CKD): progressive, long-term decline in kidney function lasting 3 mos or
longer
○ irreversible structural damage & persistent reduction in GFR (< 60 mL/min)
○ permanent & often progressive w/o treatment
○ Causes:
Leading cause = Diabetes mellitus
Second-leading cause = HTN
chronic glomerulonephritis, polycystic kidney disease, recurrent infections,
autoimmune diseases (SLE)
○ Stages:
 Renal insufficiency (moderate CKD–stages 3 &4; eGFR b/w 15-59 mL/min)
Renal failure/End-Stage (ESRD–stage 5; eGFR 40 years old
○ family hx
○ obesity
○ cardiovascular disease
○ type 2 DM
○ lack of exercise
○ ED
Prostate gland enlargement:
○ often d/t hormonal changes (higher proportion of estrogen & accumulation of DHT)
○ compresses the urethra, leading to partial or complete obstruction
○ Clinical manifestations:
weak stream, hesitancy
postvoid dribbling
frequency of urination
nocturia
Increased smooth muscle tone:
○ hyperplasia of smooth muscle & connective tissue exacerbates urethral compression & urinary
obstruction
Detrusor instability & impaired bladder contractility:
○ increased resistance to urine flow increases workload of the bladder, leading to detrusor muscle
hypertrophy & reduced compliance

○
○ Clinical manifestations:
 straining to urinate
prolonged urination
sensation of incomplete emptying
urinary urgency & frequency, occasional urge incontinence, double-voiding
Important lab marker: Prostate-specific antigen (PSA)
○ elevated in both BPH & prostate cancer