Urinary System

Question 1

Wastes disposed by kidney

Answer 1

• Nitrogenous wastes (excrete liquid waste)
• Toxins
• Drugs
• Excess ions

Question 2

Regulatory functions of kidney

Answer 2

▪ Production of renin to maintain blood pressure and volume by controlling volume of water
▪ Regulate pH and osmolarity of blood, control concentration of various ions in blood
▪ Production of erythropoietin and renin to stimulate red blood cell production
▪ Conversion of vitamin D to its active form

Question 3

Locations of kidneys

Answer 3

▪ The kidneys are situated against the dorsal body wall in a retroperitoneal position (behind the parietal peritoneum)
▪ Peritoneum – membrane which lines the abdominal cavity
▪ The kidneys are situated at the level of the T12 to L3 vertebrae
▪ The right kidney is slightly lower than the left (because of position of the liver)

Question 4

Structure of kidneys

Answer 4

▪ An adult kidney is about 12 cm (5 in) long and 6 cm (2.5 in) wide
▪ Convex lateral edge, concave medial surface
▪ Renal hilum
▪ An adrenal gland sits atop each kidney
▪ Two lowest ribs protects kidneys from blows from behind

Question 5

What is the renal hilum

Answer 5

• A medial indentation where several structures enter or exit the kidney (ureters, renal blood vessels, and nerves)

Question 6

3 protective layers that enclose the kidney

Answer 6

▪ Fibrous capsule encloses each kidney
▪ Perirenal fat capsule surrounds the kidney and cushions against blows
▪ Renal fascia is the most superficial layer that anchors the kidney and adrenal gland to surrounding structures

Question 7

3 regions of the longitudinal section in the kidneys

Answer 7

1. Renal cortex—darker outer region
2. Renal medulla—deeper region divided in to renal (medullary) pyramids (triangular regions of tissue in medulla)
   Renal columns—inward extensions of cortex like tissue that separate the pyramids
3. Renal pelvis—medial region that is a flat, funnelshaped tube, deepest part of kidney ▪ Calyces form cup-shaped “drains” that enclose the renal pyramids ▪ Calyces collect urine and send it to the renal pelvis, on to the ureter, and to the urinary bladder for storage

Question 8

Blood Supply amount and movement

Answer 8

▪ One-quarter of the total blood supply of the body passes through the kidneys each minute
▪ 20-22% of the blood pumped by heart under resting conditions goes to kidneys
▪ Renal artery provides each kidney with arterial blood supply
▪ Renal artery approached hilum and divides into segmental arteries → interlobar arteries (travel through medulla to cortex) → arcuate arteries (at junction between medulla and cortex) → cortical radiate arteries (supplies renal cortex)

Question 9

Explain venous flow

Answer 9

▪ Arterial supply in reverse
▪ Cortical radiate veins → arcuate veins → interlobar veins → renal vein
▪ There are no segmental veins
▪ Renal vein returns blood to the inferior vena cava

Question 10

What are nephrons and its 2 main structures

Answer 10

▪ Structural and functional units of the kidneys
▪ Each kidney contains over a million nephrons
▪ Each nephron has its own blood supply and creates urine which passes through collecting duct to the renal pelvis consists of two main structures 1. Renal corpuscle 2. Renal tubule

Question 11

Two divisions of renal corpuscle

Answer 11

Glomerulus and Glomerular capsule

Question 12

Glomerulus

Answer 12

a knot of capillaries made of podocytes. Blood enters through afferent arteriole and exits through efferent arteriole

• Podocytes (foot processes that cling to the glomerulus)
• Filtration slits create a porous membrane – ideal for filtration
• As blood passes through the capillaries, lot of the plasma leaks through the endothelial cells of the capillaries
• It then leaks through the filtration slits of the surrounding podocytes into the glomerular capsule.
• After processing, this becomes urine.

Question 13

Glomerular capsule

Answer 13

a cup-shaped structure that surrounds the glomerulus
- First part of the renal tubule
- Has an inner and outer surface
o Between the area, there is a hollow space called glomerular capsular space

Question 14

Positioning and subdivisions of renal tubule

Answer 14

▪ Extends from glomerular capsule and ends when it empties into the collecting duct
▪ From the glomerular (Bowman’s) capsule, the subdivisions of the renal tubule are: 1. Proximal convoluted tubule (PCT) 2. Nephron loop (loop of Henle) 3. Distal convoluted tubule (DCT)

Question 15

Steps of fluid flow through renal tubule

Answer 15

1. Proximal convoluted tubule begins at glomerular capsules.
2. Fluid in these capsules passes into the PCT.
3. Fluid then enters nephron loop (descending and then ascending limb). Descending and lower part of the ascending limb have thinner walls than PCT and DCT.
4. When fluid reaches thick part of ascending limb, it enters the DCT.
5. Fluid that reaches the end of DCT, enters the collecting duct.
6. Each collecting duct receive fluid from various nephrons. It merges into larger ducts and ultimately drains into hollow renal pelvis.

Question 16

Cortical nephrons

Answer 16

Located entirely in the cortex ▪ Include most nephrons, short nephron loops (penetrate slightly into medulla)

Question 17

Juxtamedullary nephrons

Answer 17

▪ Found at the cortex-medulla junction ▪ Nephron loop dips deep into the medulla

Question 18

Nephron capillary beds

Answer 18

1. Glomerulus 2. Peritubular capillary bed

Question 19

Duties of glomerulus in nephrons

Answer 19

Fed and drained by arterioles
▪ Afferent arteriole—arises from a cortical radiate artery and feeds the glomerulus
▪ Efferent arteriole—receives blood that has passed through the glomerulus, larger diameter, higher blood pressure in glomerular capillaries, forces fluid and small cellutes out into the glomerular capsule
Specialized for filtration (unique as both drained and fed by arterioles)
High pressure forces fluid and small solutes out of blood and into the glomerular capsule
Most of these are reclaimed by renal tubule cells and returned to blood in peritubular capillary beds

Question 20

Peritubular capillary beds

Answer 20

▪ Arise from the efferent arteriole of the glomerulus
▪ Low-pressure, porous capillaries
▪ Adapted for absorption instead of filtration
▪ Cling close to the renal tubule to receive solutes and water from tubule cells
▪ Drain into the interlobar veins leaving the cortex

Question 21

Processes of urine formation

Answer 21

1. Glomerular filtration 2. Tubular reabsorption 3. Tubular secretion

Question 22

Glomerular filteration

Answer 22

▪ The glomerulus is a filter
▪ Filtration is a nonselective passive process –
Water and solutes smaller than proteins are forced through glomerular capillary walls ▪ Proteins and blood cells are normally too large to pass through the filtration membrane ▪ Once in the capsule, fluid is called filtrate ▪ Filtrate leaves via the renal tubule
To reach the glomerular capsular space, the water and fluid must cross the endothelial cells, basement membrane and podocytes of the glomerular capsule. Collectively known as filtration membrane.
Glomerular filtration rate – normal value for 125ml/min for male and 105ml/min for females
Driving force for this filtration is pressure.

Question 23

Hydrostatic and osmotic pressure

Answer 23

Hydrostatic pressure occurs as a result of blood being pushed into the afferent arteriole. Pushes blood from high to low pressure.

Osmotic pressure is created by the presence of dissolved substances in water. High osmotic pressure pulls in water from low osmotic pressure areas.

Question 24

Tubular reabsorption

Answer 24

Begins as soon as filtrate enters PCT
tubule cells are transporters taking up needed substances from filtrate and then passing them out to extracellular space from which they are absorbed into the peritubular capillary blood.
Some reabsorption is done passively. Eg. Water passes by osmosis
Active transport most common – require ATP, membrane carriers and are very selective
▪ The peritubular capillaries reabsorb useful substances from the renal tubule cells, such as: ▪ Water ▪ Glucose ▪ Amino acids ▪ Ions
▪ Most reabsorption occurs in the proximal convoluted tube (DCT and collecting duct are still active)

Question 25

Tubular secretion

Answer 25

▪ Reabsorption in reverse
▪ Some materials move from the blood of the peritubular capillaries into the renal tubules to be eliminated in filtrate ▪ Hydrogen and potassium ions ▪ Creatinine
▪ Secretion is important for: ▪ Getting rid of substances not already in the filtrate ▪ Removing drugs and excess ions ▪ Maintaining acid-base balance of blood (pH)
▪ Materials left in the renal tubule move toward the ureter

Question 26

Nitrogenous waste

Answer 26

Nitrogenous Waste
▪ Nitrogenous waste products are poorly reabsorbed, if at all
Tend to remain in the filtrate and are excreted from the body in the urine in high concentrations
Urea and Uric acid, Creatinine

Question 27

What is urea, creatinine and uric acid

Answer 27

▪ Urea—end product of protein breakdown (when amino acids are used to form energy) ▪ Uric acid—results from nucleic acid metabolism ▪ Creatinine—associated with creatine metabolism in muscle tissue

Question 28

Difference between urine and filterate

Answer 28

▪ Filtrate contains everything that blood plasma does (except proteins). As filtrate has reached collecting ducts it has lost almost all of its nutrients and water ▪ Urine is what remains after the filtrate has lost most of its water, nutrients, and necessary ions through reabsorption ▪ Urine contains nitrogenous wastes and substances that are not needed

Question 29

Characteristics of urine

Answer 29

▪ Clear and pale to deep yellow in color
▪ Yellow color is normal and due to the pigment urochrome (from the destruction of hemoglobin) and solutes
▪ Dilute urine is a pale, straw color
▪ Sterile at the time of formation
▪ Slightly aromatic, but smells like ammonia with time
▪ Slightly acidic (pH of 6)
▪ Weighs more than distilled water (due to contained nutrients)
▪ Specific gravity of 1.001 to 1.035

Question 30

Solutes found in urine

Answer 30

▪ Sodium and potassium ions ▪ Urea, uric acid, creatinine ▪ Ammonia ▪ Bicarbonate ions

Question 31

Solutes not found in urine

Answer 31

▪ Glucose ▪ Blood proteins ▪ Red blood cells ▪ Hemoglobin ▪ WBCs (pus) ▪ Bile

Question 32

What are Ureters

Answer 32

▪ Slender tubes 25–30 cm (10–12 inches) attaching the kidney to the urinary bladder:
Continuous with the renal pelvis ▪ Enter the posterior aspect of the urinary bladder ▪ Run behind the peritoneum
▪ Peristalsis aids gravity in urine transport
Lined with epithelium and contains smooth muscles in its wall

Question 33

Explain the urinary bladder

Answer 33

▪ Smooth, collapsible, muscular sac situated posterior to the pubic symphysis
▪ Stores urine temporarily
▪ Sits on the floor of the pelvic cavity in front of vagina and uterus in females
▪ Trigone—triangular region of the urinary bladder base based on three openings ▪ Two openings from the ureters (ureteral orifices) ▪ One opening to the urethra (internal urethral orifice)
▪ In males, the prostate surrounds the neck of the urinary bladder

Question 34

Urethra location and length

Answer 34

Length
▪ In females: 3 to 4 cm (1.5 inches long) ▪ In males: 20 cm (8 inches long)
Location
▪ Females—external opening is anterior to the vaginal opening
▪ Males—travels through the prostate and penis ▪ Prostatic urethra ▪ Membranous urethra ▪ Spongy urethra

Question 35

Urethra features and functions

Answer 35

▪ Thin-walled tube that carries urine from the urinary bladder to the outside of the body by peristalsis
Function ▪ Females—carries only urine ▪ Males—carries urine and sperm (never at the same time)
Release of urine is controlled by two sphincters
1. Internal urethral sphincter ▪ Involuntary and made of smooth muscle – keeps urethra closed if urine isn’t passed
2. External urethral sphincter ▪ Voluntary and made of skeletal muscle

Question 36

Micturition

Answer 36

▪ Voiding, or emptying of the urinary bladder
▪ Two sphincters control the release of urine, the internal urethral sphincter and external urethral sphincter
▪ Bladder collects urine to 200 ml
▪ Stretch receptors transmit impulses to the sacral region of the spinal cord
▪ Impulses travel back to the bladder via the pelvic splanchnic nerves to cause bladder contractions
▪ When contractions become stronger, urine is forced past the involuntary internal sphincter into the upper urethra
▪ Urge to void (empty bladder) is felt
▪ The external sphincter is voluntarily controlled, so micturition can usually be delayed (eventually occurs if convenient or not)

Question 37

What does blood composition depend on

Answer 37

1. Diet 2. Cellular metabolism 3. Urine output

Question 38

4 roles of kidney in maintaing blood composition

Answer 38

1. Excreting nitrogen-containing wastes
2. Maintaining water balance of the blood
3. Maintaining electrolyte balance of the blood
4. Ensuring proper blood pH

Question 39

3 main fluid compartments of the body

Answer 39

1. Intracellular fluid (ICF) 40% of body weight ▪ Fluid inside living cells ▪ Accounts for two-thirds of body fluid
2. Extracellular fluid (ECF) ▪ Fluids outside cells; includes blood plasma, interstitial fluid (IF), lymph, and transcellular fluid (CSF, humours of the eyes, etc.,)
3. Plasma (blood) is ECF, but accounts for 3L of total body water. ▪ Links external and internal environments

Question 40

Link between water and electrolytes

Answer 40

▪ Electrolytes are charged particles (ions) that conduct electrical current in an aqueous solution ▪ Sodium, potassium, and calcium ions are electrolytes are also important to body homeostasis

Question 41

Regulation of water intake and output

Answer 41

▪ Water intake must equal water output if the body is to remain properly hydrated
▪ Sources for water intake - Ingested foods and fluids ▪ Water produced from metabolic processes (10%) ▪ Thirst mechanism is the driving force for water intake
If large volumes are lost, kidneys compensate by losing less urine to retain fluid volume

Question 42

What is the thirst mechanism

Answer 42

▪ Osmoreceptors are sensitive cells in the hypothalamus that become more active in reaction to small changes in plasma solute concentration
▪ When activated, the thirst center in the hypothalamus is notified
▪ A dry mouth due to decreased saliva also promotes the thirst mechanism
When less fluid leaves the blood stream, less saliva is produced, reinforcing thirst response
Also reinforced when blood volume or pressure declines
▪ Both reinforce the drive to drink

Question 43

Chain of events when blood volume drops

Answer 43

1. Arterial pressure drops which reduces filtrate volume or solute content in renal tubules.
2. Hypothalamic osmoreceptors becomes more active and nerve impulses are sent to posterior pituitary to release ADH.
3. This hormone prevents excessive water loss in urine, by allowing reabsorption of water in collecting ducts of kidneys. Blood volume increases due to increase water absorption.
4. ADH is released continuously unless solute concentration of blood drops too low.
5. Activity of osmoreceptors decreases and excess water is allowed to leave in the urine.

Question 44

Maintaining electrolyte balance

Answer 44

▪ Small changes in electrolyte concentrations cause water to move from one fluid compartment to another
- Movement alters blood volume, blood pressure and impairs activity of excitable cells (nerve, muscle cells)
▪ A second hormone, aldosterone, helps regulate blood composition and blood volume by acting on the kidney
▪ For each sodium ion reabsorbed, a chloride ion follows, and a potassium ion is secreted into the filtrate
o Sodium – electrolyte most important for osmotic water flow (when blood ion concentration is low, water leaves the blood and enters tissue  causes edema or swelling)
▪ Water follows salt: when sodium is reabsorbed, water follows it passively back into the blood  blood volume and pressure increase

Question 45

Renin-angiotensin mechanism

Answer 45

▪ Most important trigger for aldosterone release
▪ Mediated by the juxtaglomerular (JG) apparatus of the renal tubules
▪ When cells of the JG apparatus are stimulated by low blood pressure in efferent arteriole , the enzyme renin is released into blood
▪ Renin catalyzes reactions that produce angiotensin II
▪ Angiotensin II causes vasoconstriction and aldosterone release (through stimulation of adrenal cortex)
▪ Result is increase in blood volume and blood pressure

Question 46

Maintaining Acid-Base Balance of Blood

Answer 46

Blood pH must remain between 7.35 and 7.45 to maintain homeostasis and allow cells to function properly
▪ Alkalosis—pH above 7.45 ▪ Acidosis—pH below 7.35 ▪ Physiological acidosis—pH between 7.0 and 7.35
▪ Although small amounts of acidic substances are from food, hydrogen ions originate from biproducts of cellular metabolism  continuously adds substances to blood which disturb acid-base balance
▪ Kidneys play greatest role in maintaining acid-base balance
▪ Other acid-base controlling systems: ▪ Blood buffers ▪ Respiration (eliminating CO2)

Molecules react to prevent dramatic changes in hydrogen ion (H+) concentrations
▪ Bind to H+ when pH drops ▪ Release H+ when pH rises

Question 47

3 major chemical buffer systems

Answer 47

1. Bicarbonate buffer system 2. Phosphate buffer system 3. Protein buffer system
   - All work together  If hydrogen ion concentration changes in one compartment, it changes in the others as well. Therefore, any abnormal pH is resisted by the entire buffering system

Question 48

Respiratory mechanism

Answer 48

• When C02 enters blood from tissues, most enters the RBCs and is converted to bicarbonate ions for transport in the plasma
• C02 is expelled from lungs at same rate it is formed in tissues. Therefore, hydrogen ions released when C02 is loaded into blood are not allowed to accumulate as they are tied up in water, when C02 is unloaded from the lungs
• Under normal conditions  hydrogen ions produced by C02 have essentially no effect on blood pH
• However, when C02 accumulates in blood (during restricted breathing) more hydrogen ions are released to blood via metabolic processes  chemoreceptors in respiratory control centres in brain are activated  breathing rate and depth increase  excess hydrogen ions are removed as more C02 is removed from the lungs
• When blood pH rises  respiratory centre is depressed  respiratory rate and depth decrease  C02 and hydrogen ions accumulate in blood  blood pH is restored to the normal range

Question 49

Renal mechanism

Answer 49

• Chemical buffers can tie up excess acids or bases temporarily but cannot eliminate them from the body
• Although lungs can eliminate carbonic acid by removing C02, only kidneys can remove other acids generated during metabolism
• Only kidneys can regulate pH of alkaline substances. Therefore, although they act slowly and require hours or days to change blood pH  provide most effect way to regulate acid and base balance
  ▪ When blood pH rises: ▪ Bicarbonate ions are excreted ▪ Hydrogen ions are retained by kidney tubules (most effective)
  ▪ When blood pH falls: ▪ Bicarbonate ions are reabsorbed and generated ▪ Hydrogen ions are secreted
  ▪ Urine pH varies from 4.5 to 8.0
• Reflects ability of kidneys to excrete basic or acid ions to maintain blood pH homeostasis

Question 50

Diabetes mellitus

Answer 50

▪ Diabetes mellitus is a condition in which urine output is abnormally elevated due to large amount of glucose
- Develops when body fails to produce insulin or when body cells fail to respond to insulin
- Glucose is usually filtered by the glomerulus and fully reabsorbed in the Renal Tubules, however, too much enters tubules and tubules cannot reabsorb all the glucose
- Urine has sweet smell
Excess glucose creates osmotic pressure and leads to less water reabsorption and more urine production
- Long term – may lead to kidney damage or diabetic neuropathy which can lead to renal failure or chronic kidney disease

Question 51

Diabetes insipidus

Answer 51

characterised by the production of large amounts of urine that is highly diluted
- Caused by failure of the pituitary gland to produce ADH
o Little or no water is reabsorbed if kidney cannot respond to ADH

Question 52

Chronic kidney disease

Answer 52

associated with a long term decrease in glomerular filtration rate
- Less than 60ml per min for 3 months
- Developed slowly and can lead to renal failure (less than 15ml – most severe stage)
o Need kidney transplant or receive renal dialysis
- Most commonly caused by diabetes mellitus or high blood pressure

Question 53

Kidney stone

Answer 53

is a solid crystalline mass that forms in the urine

• Made from calcium containing compounds or magnesium or uric acid
• Greater fluid intake increases flow rate of urine and reduces the chance of crystallisation

Question 54

Urinary tract infections

Answer 54

usually caused by bacteria that enter the urethra at its outside opening

• More common in women due to shorter urethra
• Bacteria can more easily lead the bladder
• Can travel up the urethra and infect the kidney