RenalObjectives.docx

Transcript

**RENAL STUDY GUIDE**

**RENAL AND URINARY TRACT ANATOMY**

***Functions of the Kidney: Homeostasis, Endocrine, and Metabolic***

- - - - - - - -

***Renal Vasculature***

- - - - - - - -

***Blood Flow Through the Kidney***

- Capillaries in the kidneys go from artery artery

- 30% of the population has more than 1 artery supplying a kidney

- Segmental arteries do not have collateral vessels

- Long term overactivity of the SNS can lead to decreased kidney
function as well as cardiac hypertrophy

***Urologic System Functions***

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***Flow Through the Kidney:***

- -

***Renal Anatomy: 2 kidneys, 2 ureters, 1 bladder (detrusor and trigone
muscles), 1 urethra (3-4 cm in women; 18-20 cm in
men)***

-

- -

- - - - - - **Parasympathetic innervation of bladder and
internal urethral sphincters**. -- Allows you to voluntarily
void

- SNS innervates bladder neck, vas deferens, seminal vesicles,
prostate.

- Skeletal muscle motor neurons in external urethral sphincter.
Pudendal nerve.

**Nephron:** Functional unit of the kidney. Each
kidney contains 1 million nephrons.

- - -

***Nephron Contains:***

**In Renal Cortex:**

- - -

- **[Mesangial Cells ]**

- Contractile cells with macrophage like properties/immune
defense/repair of glomerulus

- Regulate capillary flow and surface area available to form
ultrafiltrate

- Clear the endothelial cells and podocytes of protein

- **[Bowman's Capsule]**

- Epithelial cup surrounding capillaries where filtrate collects
to go onto tubules

- - **Function: bulk reabsorption of solutes and water into blood**

- **Sodium (65%) is actively transported from the proximal
tubule and into the peritubular interstitial; consumes a
large quantity of oxygen**

- Potassium, chloride, and bicarbonate follow sodium in direct
proportion by the sodium co-transport mechanism -- 65% of
these ions are also reabsorbed here

- Water (65%) follows sodium by osmosis/passive diffusion
("where sodium goes, water goes")

- **Reabsorption of water leaves an increased concentration of
urea**

- **Glomerulotubualr balance - Reabsorption of sodium and water is
proportional in the PCT**

- **When the GFR spontaneously decreases
or increases, the renal tubules (primarily the proximal
tubules) automatically adjust their rate of reabsorption of
sodium and water to balance the change in GFR**

- Solute secretion, hormone production, gluconeogenesis

- - **Function**: establish a hyperosmotic state with the medullary
interstitial fluid; participate in forming concentrated or
dilute urine. **The Loop of Henle separates the handling of
water and sodium.**

- **The ability of the kidneys to produce concentrated or dilute
urine depends on the presence of a graduated hyperosmotic
peritubular interstitium. Must be an osmotic gradient across the
renal medulla to produce variable urine concentration.**

- **Two countercurrent systems are needed to create and maintain
the graduated hyperosmotic peritubular interstitum:**

- **Loop of Henle -- countercurrent multiplier system that
creates the osmotic gradient**

- **Vasa recta -- countercurrent exchanger system that
maintains the medullary osmotic gradient**

- **Returns the reabsorbed water to the blood, allowing
the osmolarity in the interstitum to remain high**

- Without this, we would produce dilute urine, leading to
dehydration

- **Thin, descending segment** -- highly permeable to water and
moderately permeable to sodium, urea, and other solutes (less
mitochondria/microvilli)

- **20% of water is reabsorbed here (back to peritubular
capillaries)**

- **Concentrates NaCl in the tubular
fluid, which is delivered to the thick ascending limb**

- Hyperosmotic fluid causes water to leave the descending
limb; the remaining ultrafiltrate (fluid) becomes
increasingly concentrated

- The osmolarity of the peritubular interstitum progressively
increases as the descending limb travels from the cortex to
the medulla (300-1500 in the renal pelvis). The increasing
osmolarity provides the energy for passively reabsorbing
water (osmosis).

- **Thin, ascending segment** -- more permeable to solutes and
almost impermeable to water (more microvilli/mitochondria to
transport sodium actively and dilute the urine) -- pumps out
salt

- **Thick, ascending segment** -- highly permeable to sodium,
potassium, and chloride and significantly less permeable to
water and urea (more microvilli/mitochondria to transport sodium
actively and dilute the urine)

- Uses active transport to move chloride and sodium into the
medullary interstitum

- Water cannot follow sodium into the peritubular interstitum so
the tubular fluid becomes dilute and the peritubular
interstitium becomes concentrated.

- **Thick ascending limb pumps out sodium -- makes the environment
super salty, so when new filtrate enters through the descending
limb water will passively leave due to the salty interstitial
space/renal medulla -- saltiness does not get diluted with water
because it is reabsorbed by blood (why we aren't dehydrated!)**

- Fluid leaving the ascending limb of the loop is hypoosmotic and
is more diluted than the fluid that entered

- Ultrafiltrate/fluid becomes more and more dilute as it
encounters the distal tubule

- - Sodium is reabsorbed, and potassium, chloride and
bicarbonate follow

- **The late distal tubule is almost impermeable to water
except in the presence of aldosterone (Na and water) or ADH
(just water);** these hormones can fine tune the final urine
concentration

- - Performs final adjustments in urine composition (work on
solutes, not water -- limited permeability)

- K, Na is absorbed by distal tubule and collecting duct
due to aldosterone

- **Straight segment of the distal tubule and the collecting
duct is permeable to water as controlled by ADH or
aldosterone**

- **ANP inhibits water and sodium reabsorption**

- Tamm-Horsfall glycoprotein (uromodulin) -- protective
mechanism

- Most abundant urinary protein

- Protects against bacterial adhesion and urolithiasis
(kidney stones)

- Renal ligand for lymphokines

- Damage to distal convoluted tubules/collecting duct,
increased risk of infection

- -

-

**Urine Formation/Nephron functions:** **1. Glomerular filtration**,
**2. Tubular Reabsorption**, **3. Tubular Secretion 4. Excretion**

- Renal blood flow is one factor that affects GFR, **RBF DOES NOT**
equal Pressure

- RBF originates at kidney's hilum

- Kidneys receive 1000-2000 mL of blood per minute

- GFR -- filtration of plasma into Bowman space

- 20% of RBF (120-140 mL/min) becomes filtrate

- Directly r/t to the perfusion pressure in the glomerular
capillaries

- Renal Plasma Flow = RBF minus RBCs (and other blood cells)

- Amount of blood volume that reaches the glomerulus

- Not all of that 1L blood/min is filtered -- blood cells are not

- In normal kidneys, RBF \~635 mL/min

- - **Amount of fluid that flows into Bowman's capsule per unit of
time**

- **Normal: 90-120 mL/min**

- **20% of renal blood flow is filtered by the glomerulus, 80% is
delivered to the peritubular capillaries (water, electrolytes,
and glucose are freely filtered. Plasma proteins are not).**

- - - - -

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**Filterability of substances is determined by:**

- -

***Why do glomerular capillaries have higher filtration rates?*** ↑
Hydrostatic Pressure, ↑ Capillary filtration coefficient


***Starling Forces & GFR***

- - - **Capillary Hydrostatic pressure drops as blood travels
through the capillary bed into the venules and veins**

- **Capsular hydrostatic pressure -- pressure the fluid in the
glomerular capsule exerts against the filtration membrane**

- - - *Decreasing the efferent arteriolar resistance increases the
RBF through the glomerulus, but it decreases the hydrostatic
pressure in the glomerulus, thus GFR decreases*

- *Vasoconstriction leads to increased resistance*

**Forces Favoring Filtration:**

- - **3 DETERMINANTS -- ARTERIAL BP, AFFERENT PRESSURE, AND EFFERENT
PRESSURE**

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**Forces Opposing Filtration:**

- - -


The net filtration pressure is the driving force that pushes fluid from
the blood (glomerulus) into Bowman's capsule.

**To calculate GFR:**

- -

- - -

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- - -

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*2 Mechanisms of Autoregulation:*

- - **Without autoregulation, when MAP decreases or vascular
resistance increases, then the RBF would decrease!**

- **When renal perfusion is too low, autoregulation increases
renal blood flow by reducing renal vascular resistance**

- **When renal perfusion is too high, autoregulation decreases
renal blood flow by increasing renal vascular resistance**

- Balances pressure between afferent and efferent arterioles

- **When renal perfusion is 80-180, there is a constant RBF and
GFR**

- **Sustaining renal perfusion via autoregulation translates
to a systemic MAP \~/\> 65-80 (highly dependent on DBP)**

- Prevents wide fluctuations in systemic arterial pressure from
transmitting to glomerular capillaries

- Ex: As the systemic BP increases, afferent arterioles constrict,
preventing an increase in filtration/hydrostatic pressure

1. **Myogenic:** immediate. impact of arterial pressure on renal
arterioles.

- -

2. **Tubuloglomerular Feedback:** delayed (seconds to minutes later).
Macula densa feedback.

- - -

**Neural Regulation:**

- - **No parasympathetic effects!**

- - -

**Hormone Regulation: Affect RBF and GFR!**

- - -

- - V2 receptors on collecting ducts.

- Controls final concentration of urine

- Regulates aquaporin expression

- - Inhibit Na & H~2~O reabsorption by kidney tubules. Inhibit
secretion of Renin & Aldosterone. Vasodilate afferent arterioles
& constrict efferent arterioles → to ↑ urine formation and ↓
blood volume & BP. ↑ water loss

- A type -- myocardial cells in atria

- B type -- secreted from myocardial cells in the ventricles

- - - - **Activated alpha 1 receptors promote afferent arteriole
vasoconstriction, decreasing GFR and RBF**

- **Increases sodium reabsorption in proximal tubule**

- - - -

***In ↓ Renal Perfusion:*** (Myogenic autoregulation & Vasodilatory PGE
→ Afferent vasodilation) & (↑ Angiotensin II → Efferent
Vasoconstriction) = **MAINTENANCE OF GFR.**

**Urine Formation** (**Tubular reabsorption** & **Tubular Secretion**)
-- tubular transport back into the plasma

- - **Approx. 60 -- 70% of filtered sodium and water and approx. 50%
of urea are reabsorbed, along with 90% or more of potassium,
glucose, bicarbonate, calcium, phosphate, amino acids, and uric
acid.**

- **Active Transport**

- **Can become limited as carrier molecules become saturated**

- **Facilitated Transport**

- **Used to move filtrate solutes like glucose into
interstitial fluid and peritubular capillaries**

- **Passive diffusion is used to reabsorb chloride, water and
urea**

- **Damaged renal tubules -- metabolic byproducts and drugs may
accumulate, causing toxicity**

- **[Proximal Convoluted Tubules]**

- **[Loop of Henle ]**

- **[Distal Convoluted tubules and collecting duct ]**

- **[Mechanisms of Urine Concentration and Dilution]**

- Urea (end product of protein metabolism and major
constituent of urine)

- Formed by liver from ammonia

- Filtered into the renal capsule, limited reabsorption in
tubules

- Urea is moved from filtrate into the interstitum at
the medullary tubules (via facilitated diffusion),
creating a concentration gradient pulls water into
interstitum

- This pull concentrates urine

- Urea is then secreted in the thin ascending limb

- Under the influence of ADH, urea moves back into the
interstitum at the distal tubule

- 50% of urea is excreted in the urine 50% is retained in
interstitial fluid in kidneys

- Countercurrent multiplier/Exchange -- **look up video on
this...**

- **Occurs in extra long Loops of Henle**

- An osmotic gradient in the medullary interstitial fluid
is created

- Produces concentrated urine

- The longer the loop, the greater the concentration
gradient/concentration ability

- - **Can be unidirectional or bidirectional**

- **Ex: secretion from peritubular capillaries through
interstitial fluid, then back through tubular epithelial
cells**

- **Secreted substances include: urea, creatinine, caffeine. Many
antibiotics, potassium, acids, and bases.**

- **4. Tubular Excretion**: the result of filtration, absorption, and
secretion processes

- Urine is the product

- Transfer of solutes (that are too large to be filtered by the
glomerulus or are in excess in the blood) form the peritubular
capillaries to the renal tubular lumen → urinary excretion
(active transport)

- The process by which metabolites, molecules, drugs and the like
are IRREVERSIBLY transferred from the internal to the external
environment

- Factors that alter excretion: urine pH, binding to proteins,
diseases states, negative, changes in GFR

**Renal Function Tests**

- - Best way to estimate the functioning of renal tissue (normal =
120/min)

- **Directly measured by the clearance of exogenous filtration
markers**

- Requires 24 hour urine collection + 1 blood sample; multiple
blood collections; nuclear renal scan

- Accurate and expensive

- **Estimated/calculated indirectly by endogenous markers (serum
creatinine and cystatin C**)

- Widely used, acceptable and cheap

- Inaccurate and imprecise unless GFR \20 and oliguric [ ]**-- consider renal injury,
ATN

- **\>20 and hyponatremic** -- consider renal salt wasting,
cerebral salt wasting, SIADH, adrenal insufficiency, diuretic
use

- - Plasma protein is freely filtered at the glomerulus

- Measures progressive renal dysfunction

-

**Urinalysis Tests Kidney Function**

- **Urine color/clarity**

- **Urine pH** (5-6.5)

- **Specific gravity** (1.016-1.022)

- **Urine osmolality (300-900 mOsm/kg)**

- More accurate than specific gravity in the presence of urea and
glucose

- High in pre-renal AKI

- **Urine sediment**

- **Reagent strips**

- **Leukoesterase (negative) --** enzyme in WBCs, indicates
infection

- **Nitrates (negative) --** byproduct of bacterial metabolism,
indicates infection

- If you have hematuria (one time), repeat test

- Avoid ordering follow up urine cultures after treatment of
uncomplicated UTI in patients that show clinical resolution of
infection

-

**[Quiz Questions:]**

1\. When a cell shrinks after being placed in an aqueous solution, the
solution is most likely hypotonic. **False**

2\. When the juxtamedullary nephrons are all non-functional, a person's
risk for dehydration increases. **True**

3\. Increased blood volume will inhibit proximal tubule reabsorption.
**True (When BP or blood volume is increased, the kidneys reduce sodium
and water reabsorption in the proximal tubules to return blood pressures
and fluid volume to normal)**

4\. ADH acts to concentrate urine by stimulating the reabsorption of
sodium chloride and water in the proximal tubule. **False**

5\. The countercurrent exchange in the kidney is associated with shorter
loops of Henle. **False**

6\. If a person's glomerular filtration membrane has been injured, which
structures would be affected? **Podocytes**

7\. One of the forces favoring filtration in the glomerulus is:
**capillary hydrostatic pressure**

8\. The primary function of the Loop of Henle is to: **establish a
hyperosmotic state within the medullary interstitial fluid.**.

**General Kidney Fluid and Electrolyte Balance**

- **Basic Concepts**

- **Tonicity -- iso, hypo, hyper**

- **Osmolarity -- mOsm/L**

- **Concentration gradients -- result from unequal distribution of
water or solute across a semipermeable membrane**

- **Total body water- 60% of body weight**

- **ICF 40% body weight; ECF 20% of body weight**

- **ICF and ECF are separated by a semipermeable membrane**

- **Non-penetrating solutes (ions) need assistance**

- **Sodium**

- **Hypernatremia can result from net gain of salt or net loss of
water**

- **Hyponatremia can result from net loss of salt or net gain of
water (alcoholics, SSRIs)**

- **Pseudohyponatremia can occur from hyperglycemia,
hyperlipidemia, high serum proteins, hyperuremia**

- **Potassium**

- **Hyperkalemia:**

- **Increased intake**

- **Decreased urinary excretion (hypoaldosteronism, kidney
failure)**

- **Intracellular extracellular shifts (acidosis, trauma/cell
destruction, beta blockers, low insulin)**

- **Low catecholamines**

- **Low flow to distal nephron**

- **Hypokalemia:**

- **Decreased intake**

- **Increased urinary excretion (renal/diuretics or GI loss)**

- **Loop and Thiazide diuretics**

- **Extracellular intracellular shift (alkalosis, beta
agonists, hyperinsulinemia)**

- **Chloride**

- **Hyperchloremia \>122**

- **Hypothesized to cause renal hypoperfusion and AKI due to
renal vascular smooth muscle constrictor effect**

- **Hypochloremia**

**Embryonic Development**

- **Kidneys develop from:**

- **Pronephros -- connects primitive wolffian duct to cloaca as
the foundation for male sexual development**

- **Mesonephros -- nonfunctional**

- **Metanephros -- ureteric bud, metanephrogenic mesenchyme,
functional kidney**

- **Urine formation and excretion begin by the third month of
gestation**

**Age and Renal Function**

- - - - - - - - -

- - - - - - - - Why older adults are at increased risk
of AKI/CKD -- already reduced GFR


**Urinary Obstruction:** blockage of urine within the urinary tract.

- - - - - Severity is based on location (kidney, ureter,
bladder, urethra), degree of obstruction, rapidity of
occurrence, unilateral vs bilateral, acute v chronic,
etiology (calculi, carcinoma, papilla, infection, trauma,
clots, ectopy, fibrosis)

- - **Common problem**

- **Children more than adults**

- **Men more than women**

- - **Neurogenic Bladder**

- Bladder dysfunction caused by neurologic disorders; problems
with urine storage or voiding

- **Upper motor neurons**

- **Dyssynergia** -- overactive/hyper reflexive bladder
function

- **Detrustor hyperreflexia --** the bladder muscle
contracts to often and involuntarily

- **Detrusor hyperreflexia with detrusor dyssynergia** --
both the bladder and sphincter are contracting at the
same time, causing a functional obstruction of the
bladder outlet

- **Lower motor neurons**

- **Detrusor areflexia** -- underactive, hypotonic, atonic
bladder

- **Clinical Manifestations:**

- Frequent daytime voiding -- more often than every 2
hours while awake

- Nocturia -- night time voiding

- Urgency with hesitancy

- Dysuria

- Intermittency of urinary stream

- Feelings of incomplete bladder emptying, despite
micturition

- **Knowledge Check: A person has a lesion on the lower neuron
that involves the sacral micturition center. Which condition
is the person experiencing?** Detrusor areflexia

- **Hypospadias**

- Urethral meatus is located on the ventral side or underside
of the penis

- Tx: Surgery

- **Epispadias**

- Males: urethral opening is on the dorsal/top surface of the
penis

- Females: cleft along the ventral urethra usually extends to
the bladder neck

- Twice as many boys are affected as girls

- Tx: surgery may be needed

- **Bladder outlet obstruct**

- Urethral valves -- thin membranes that occlude the urethral
lumen and obstructs urinary outflow in male infants

- Tx: prenatal bladder shunting; with resection during the
first days of life

- **Exstrophy of the bladder**

- Pubic bones are separated and the lower abdominal wall and
anterior wall of bladder is missing

- **Renal aplasia/agenesis**

- **Agenesis -- kidney did not grow. Aplasia -- is the billing
code?**

- Absence of one or both kidneys

- Potter syndrome (bilateral renal agenesis) -- incompatible
with extrauterine life

- **Hypoplastic kidneys**

- Small with a decreased number of nephrons

- **Renal dysplasia**

- Results from abnormal differentiation of renal tissues
(primitive glomeruli and tubules, and non-renal tissue may
occur)

- **Polycystic kidney disease**

- Autosomal dominant mutation of PKD-1 (chromosome 16) and
PKD-2 (chromosome 4)

- Cyst formation and obstruction, accompanied by the
destruction of renal parenchyma, interstitial fibrosis,
and loss of functional neurons

- Leads to kidney failure

- Volume of cysts will decrease perfusion

- **Kidney stones**

- **Patho:**

- 80% calcium oxalate, can be combos of others

- Soluble material supersaturates urine; initial formation
in kidney medullary interstitum

- **Risks:**

- Male, inadequate fluid intake, geographic location,
temperature

- Increased fluid and calcium (if oxalate) intake may
reduce risk

- **Clinical Manifestations**

- Asymptomatic -- up to 70%

- Patients reports pain/renal colic

- Hematuria

- **Tx:**

- Manage pain

- Promote stone passage

- Expulsive drugs -- alpha blocker (tamsulosin), CCB
(nifedipine), antispasmodic agents

- Urologic consult -- remove stones using percutaneous
nephrolithotomy, ureteroscopy, laser lithotripsy

- reduce the concentration of stone forming substances

- adjust pH of urine

- increased fluid and calcium intake may reduce risk.

- - Pain (bladder distension, secondary to infection, obstructing
stone or masses)

- Changes/decrease in UOP

- Hypertension if retained Na+ and water

- Reports hematuria, pyuria

- Distended lower abdomen (hematuria, pyuria)

- Early diagnosis to prevent kidney injury

- *Beware of post obstructive diuresis caused by relief of
obstruction -- may cause fluid and electrolyte imbalance*

**Knowledge Check:**

Name 3 anatomic alterations that contribute to Urinary Incontinence.

**Obesity, pregnancy, BPH, weak pelvic floor?**

A child with unilateral renal agenesis is seen in the clinic. The nurse
realizes the child

a\. requires dialysis. **b. has a hypertrophied kidney (one remaining
kidney overgrew)**. c. may have facial anomalies. d. is more susceptible
to infections.

**Urinary Incontinence:** involuntary leakage of urine

- **Etiology:**

- Brain disease (stroke, Parkinson's, trauma)

- Associated risk with greater age, obesity, parity, family hx

- High impact activities, smoking, caffeine intake

- More common in women

- **Patho: 4 types**

- **Stress** -- weakened/damaged urethral sphincter,
weakened/damaged pelvic floor muscles

- **Urge** (overactive bladder) -- physical injury, neurologic
disease, diabetes, infection

- **Overflow** -- obstruction (BPH, kidney stones, tumor)

- **Functional** -- physical/mental disability that impairs
mobility/ability to reach the bathroom (dementia, diuretics)

- **Clinical Presentation:**

- Rapid, strong urge to urinate, little or no urge to urinate, or
inability

- Mild/small volume to total loss of bladder control

- Aggravating factors -- sneezing, coughing, laughing, UTI, meds,
pregnancy, obesity

- Alleviating factors -- avoid exercise/activity, stop meds

- **Pediatric Incontinence**

- Enuresis: at least 2x month after 6

- May be due to stress/behavior problems, family hx, boys more
common

- Tx: education, behavioral (timed voiding, fluid management),
meds: anticholinergic or alpha-blocker (daytime), desmopressin
(night)

**Renal Tumors**

- Renal adenomas: benign

- Renal cell carcinoma: most common

- **Clinical sx:**

- Hematuria -- all renal tumors are highly associated with
hematuria.

- Dull and aching flank pain

- Palpable mass in thinner individuals

- **Wilms Tumor (Nephroblastoma)** -- arises from mutations of Wilms
tumor-suppressors genes

- Embryonal tumor of the kidney

- Most common solid tumor of children, usually dx between 1-5
years of age

- Arises from proliferation of abnormal renal stem cells

- Manifestations:

- Enlarging upper abdominal mass in a healthy, thriving child

- Vague abdominal pain, hematuria, fever, and htn

- **Bladder tumors**

- **Risks:** smoking, chronic cystitis

- **Clinical Sx:**

- Hematuria

- Irritative voiding s/s

- Flank/suprapubic pain

- Fatigue

- Weight loss

**Urinary Tract Infection (UTI):** Infection of the urinary epithelium
caused by bacterial infection (urethra, bladder (cystitis),
ureters/renal pelvis/interstitium (pyelonephritis)).

- - Upper/lower -- pyelonephritis vs bladder

- Severity---sx that suggest infection beyond the bladder such as
fever, chills/rigor,

- - Cystitis E. coli

- Urethritis (chlamydia, herpes)

- Vaginitis

- - Frequency, urgency, dysuria, fever

- Suprapubic tenderness or pain

- Pelvic exam for vaginitis

- - - Uncomplicated -- 3 days of antimicrobial

- Young women

- Complicated -- a minimum of 7 days abx

- Pregnant women, men, children

**Knowledge Check**

4\. Mechanisms that protect the urinary tract from infection include a.
monocytes in the urine. **b. acidic urine.** c. decreased urine
osmolarity. d. type-I pili.

5\. A child has a UTI. Which assessment finding is most typical in this
condition? e. Enlarging asymptomatic upper abdominal mass f. Periorbital
edema that descends into the extremities g. Prodromal gastrointestinal
illness with diarrhea h. **Incontinence in a previously dry child**

**Acute Cystitis:** **painful bladder syndrome or interstitial cystitis
is not an infection**

- - **Protects the epithelial cells by preventing acids and toxins
from encountering this layer**

- Disrupted in painful bladder syndrome

- Can occur from recurrent UTIs

- -

**Pyelonephritis -- infection of the upper urinary tract**

- - - - -


- - **Complications:** kidney scarring (substitute fibrotic tissue
for functional tissue), HTN, renal failure

- **Clinical Sx:** often asymptomatic (esp. in children), UTI s/s

- **Tx:** prolonged abx with recurrent infection

-

**Vesicoureteral Reflex**

- **Retrograde urine flow from bladder into ureters or kidneys**

- **Encourages infected urine from bladder to be swept up into
kidneys causing frequent pyelonephritis**

- **Patho: caused by a congenital abnormality or ectopic insertion of
the ureter into the bladder**

- **Clinical Sx:**

- **Asymptomatic**

- **Recurrent UTIs, unexplained fever, poor growth and
development, feeding problems**

- **Family hx may reveal UTIs**

**Glomerulonephritis:** Inflammation of the glomeruli

- - **Adults -- uncommon, associated with immunocompromised, older
age**

- **Children -- pharyngitis, impetigo**

- **Patho:**

- **Noninfectious**

- **Infectious: antibodies produced against an organism react with
the glomerular endothelial cells**

- **Activation of complement, recruitment and activation of
immune cells and mediators**

- **In children (aged 5-15), post streptococcal is most common
(Group-A beta hemolytic strep)**

- **Glomerular sclerosis (scarring)**

- **Decreased glomerular perfusion (glomerular blood flow)**

- **Decreased GFR**

- **Thickening of the glomerular basement membrane with
increased permeability to proteins and RBCs**

- - - - - -

- - **Clinical Sx:**

- Sudden onset

- Edema

- HTN

- Hypercoagulability

- **Labs:**

- **Proteinuria \>500 mg/day exceeding 3-5 g/day (protein
is urine is never normal)**

- Hematuria, brown-tinged urine

- Lower serum albumin

- Declining kidney fx, decreased GFR

- **post infectious glomerulonephritis:** Inflammatory
damage to glomerular basement membrane. 7-10d post strep
infection in children. Adults post bacterial
endocarditis or viral infections (varicella/hepatitis).

- **Tx:**

- Abx

- Corticosteroids

- Cytotoxic agents

- Anticoagulants

- - **Secondary causes:**

- Diabetic neuropathy -- podocyte injury, progressive
thickening/fibrosis of glomerular basement membrane

- Lupus nephritis

- **Clinical Sx:**

- Proteinuria

- Hypercholesterolemia

- **Tx:** dialysis, transplant

- - - -

***Glomerulonephritis is the most common cause of chronic kidney disease
& end stage renal failure.***

**Hemolytic Uremic Syndrome**

- **Most common community acquired cause of acute kidney failure in
children (\31

- Frequently, increased creatinine levels

- While Serum BUN levels are high -- patient will be
asymptomatic or mildly symptomatic

- **Uremia -- more symptomatic vs azotemia**

- Syndrome of kidney failure

- Retention of toxic wastes, deficiency states, electrolyte
disorders

- GFR \ glomerulonephritis

**Acute Kidney Injury:** Sudden decline in renal function. ↓GFR, ↑BUN &
Cr (nitrogenous waste).

- A rise in serum creatinine concentration or a decline in urine
output that developed within hours to days

**Prerenal AKI:**

- Cause=hypoperfusion (d/t emboli, cardiorenal syndrome, aortic
dissection, renal vasoconstriction, cross clamping, hypovolemia)

- No intrinsic damage

- Initial onset = compensation by autoregulation and tubular feedback

- Restoration of renal blood flow with IVF, hemodynamic support, and
PRBCs can halt progression to intrarenal failure (ATN)

- Avoid NSAIDs (renal prostaglandins mediate vasodilation in the
kidney. NSAIDs reduce prostaglandin synthesis, causing renal
vasculature constriction)

**Intrarenal/Acute Tubular Necrosis (ATN)**

- Most common cause of ARF in hospitalized patients (50%)

- Intrinsic causes of ATN include ischemia and nephrotoxic drugs

- The renal medulla is more susceptible to ischemic insult

- The renal tubules use oxygen to support ionic transfer between
tubules and peritubular fluid (poor oxygenation disrupts this
mechanism)

**Postrenal AKI:**

- Cause = obstruction

- Ex: clogged Foley, ureteral stones, neurogenic bladder

- Obstruction causes increase in upstream hydrostatic pressures.
Vasoconstriction & medullary hypoxia, renal tubular & interstitial
edema, ↓GFR gradual.

Clinical Manifestations: Hours of anuria🡪 flank pain🡪 remove
obstruction🡪polyuria.

Oliguria \