Urinary System

Question 1

What components make up the urinary system?

Answer 1

The urinary system includes the kidneys, ureters, urinary bladder, and urethra.

Question 2

Where is urine formed in the body?

Answer 2

Urine is formed in the kidneys.

Question 3

How is urine transported from the kidneys to the urinary bladder?

Answer 3

Urine is transported by the ureters from the kidneys to the urinary bladder.

Question 4

Where is urine stored before it is excreted from the body?

Answer 4

Urine is stored in the urinary bladder until it is excreted.

Question 5

Through which structure is urine excreted from the body?

Answer 5

Urine is excreted from the body via the urethra.

Question 6

Where are the kidneys located within the body?

Answer 6

The kidneys are small fist-sized organs located within the abdominal cavity on either side of the midline between the levels of T12-L3.

Question 7

How are the kidneys protected and anchored in place within the body?

Answer 7

The kidneys are surrounded by layers of connective tissue and adipose tissue, which serve to protect and anchor them in place.

Question 8

What percentage of the resting cardiac output do the kidneys normally receive?

Answer 8

The kidneys normally receive 20-25% of the resting cardiac output, despite their small size (<0.5% of the body’s mass).

Question 9

Where are the kidneys situated in relation to the abdominal cavity?

Answer 9

The kidneys are in the posterior aspect of the middle of the abdominal cavity.

Question 10

Despite their small size, why are the kidneys significant in terms of blood flow?

Answer 10

Despite their relatively small size, about a quarter of the blood ejected by the heart ends up passing through the kidneys.

Question 11

What are the histological components of each kidney?

Answer 11

Each kidney consists of an outer renal cortex and an inner renal medulla, which is divided into sections called pyramids, separated by columns of cortex extending into the interior of the kidney.

Question 12

What is the single-entry point on the medial surface of each kidney called?

Answer 12

The single-entry point on the medial surface of each kidney is called the hilum or hilus.

Question 13

What structures enter and exit the kidney through the hilum?

Answer 13

Through the hilum, the ureter, renal artery, and renal vein enter and exit the kidney.

Question 14

How are the pyramids and cortex arranged within the kidney?

Answer 14

The pyramids are sections of the renal medulla, separated by columns of cortex extending into the interior of the kidney.

Question 15

What is the functional significance of the hilum in the kidney?

Answer 15

The hilum serves as the entry and exit point for structures essential for kidney function, including the ureter, renal artery, and renal vein.

Question 16

Renal cortex

Answer 16

Portions extend into the renal medulla (renal columns)

Question 17

Renal medulla

Answer 17

Consists of several cone-shaped sections (renal pyramids)

Question 18

Renal Hilum

Answer 18

Entry/exit point for the:
Ureter
Renal blood vessels
Nerves and lymphatic vessels

Question 19

What is the functional unit of the kidney?

Answer 19

The functional unit of the kidney is the nephron, which consists of a renal corpuscle and renal tubule.

Question 20

how many nephrons are extending through the renal cortex and renal pyramids of each kidney?

Answer 20

~ 1,000,000 nephrons

Question 21

what is the capillary network called?

Answer 21

glomerulus

Question 22

what is the glomerulus (capillary network) surrounded by?

Answer 22

glomerular (Bowman’s) capsule

Question 23

what does the glomerular (Bowman’s) capsule do?

Answer 23

The capsule filters the blood in the glomerulus and deposits the filtered fluid (“filtrate”) into the renal tubule

Question 24

What is formed when portions of blood are filtered into the glomerular capsule?

Answer 24

When portions of blood are filtered into the glomerular capsule, they form filtrate.

Question 25

What are the three main components of the renal tubule?

Answer 25

The renal tubule consists of a proximal convoluted tubule, loop of Henle, and distal convoluted tubule.

Question 26

What happens to the composition of filtrate as it passes through the renal tubule and distal convoluted tubules?

Answer 26

The composition of filtrate is adjusted, and urine is formed when neighboring nephrons dump their leftover filtrate into a collecting duct.

Question 27

What happens to the renal artery after entering the kidney?

Answer 27

After entering the kidney, the renal artery branches into progressively smaller arteries and arterioles that spread throughout the renal tissue.

Question 28

What structures enter a nephron’s glomerular capsule from afferent arterioles?

Answer 28

Afferent arterioles give rise to a glomerulus that enters a nephron’s glomerular capsule.

Question 29

What is the function of efferent arterioles in the kidney?

Answer 29

Efferent arterioles exit the glomerular capsule and branch into peritubular capillaries surrounding the tubular portion of the nephron.

Question 30

What happens to peritubular capillaries after surrounding the renal tubule?

Answer 30

Peritubular capillaries eventually reunite to form venules, which form progressively larger veins that drain into the renal vein.

Question 31

What is the role of the renal vein in the kidney?

Answer 31

The renal vein drains blood out of the kidney, receiving blood from progressively larger venules and veins formed by peritubular capillaries.

Question 32

Afferent arterioles

Answer 32

each gives rise to a glomerulus that enters a nephron’s glomerular capsule

Question 33

Efferent arterioles

Answer 33

exit the glomerular capsule and branch into peritubular capillaries that surround the tubular portion of the nephron

Question 34

What is glomerular filtration?

Answer 34

Glomerular filtration is the movement of water and solutes from the glomerular capillary into the glomerular capsule.

Question 35

What regulates the amount of filtrate formed in the kidneys?

Answer 35

The amount of filtrate formed, known as the glomerular filtration rate, is regulated by neural and hormonal mechanisms as well as by the kidney itself through renal autoregulation.

Question 36

How is filtrate formation regulated?

Answer 36

Filtrate formation is regulated internally by the kidney and externally by the nervous and endocrine systems.

Question 37

What is renal autoregulation?

Answer 37

Renal autoregulation refers to the kidney’s ability to regulate its own blood flow and glomerular filtration rate independently of neural and hormonal influences, thereby maintaining stable kidney function despite changes in systemic blood pressure.

Question 38

Tubular reabsorption

Answer 38

The movement of water and solutes from the tubule back into the peritubular capillaries

Question 39

where does most tubular reabsorption occur?

Answer 39

in the proximal convoluted tubule, which reabsorbs all of the filtered nutrients (e.g., glucose, amino acids) and most of the filtered water and ions

Question 40

What happens to substances within the filtrate as it moves through the tubule?

Answer 40

Many substances within the filtrate are reabsorbed back into the bloodstream as it moves through the tubule, including nutrients, water, and ions.

Question 41

What is the proximal convoluted tubule (PCT)?

Answer 41

The proximal convoluted tubule is a twisted, highly coiled tubular structure in the nephron located immediately after the glomerular capsule. It is responsible for reabsorbing the majority of filtered water and solutes, such as glucose, amino acids, and ions, back into the bloodstream.

Question 42

tubular secretions:

Answer 42

The movement of certain substances (e.g., H+, wastes, drugs) from the peritubular capillaries into the tubule and collecting duct

Question 43

where do most tubular secretions occur?

Answer 43

in the proximal convoluted tubule

Question 44

What are peritubular capillaries?

Answer 44

Peritubular capillaries are a network of tiny blood vessels surrounding the renal tubules in the kidney. They play a crucial role in reabsorbing substances from the renal tubules back into the bloodstream and in delivering substances for secretion into the tubules.

Question 45

What happens to the majority of fluid and solutes that enter the renal tubule?

Answer 45

reabsorbed back into the bloodstream.

Question 46

How are tubular reabsorption and secretion regulated?

Answer 46

by several hormonal mechanisms depending on the body’s needs.

Question 47

What role do peritubular capillaries play in renal function?

Answer 47

Peritubular capillaries deliver substances for secretion into the renal tubules and also reabsorb certain substances from the tubules back into the bloodstream.

Question 48

Give examples of hormones that act on renal tubules to adjust the composition of the filtrate.

Answer 48

Hormones such as antidiuretic hormone, parathyroid hormone, and aldosterone act on renal tubules to adjust the relative concentrations of certain substances in the filtrate to help maintain homeostasis.

Question 49

How does antidiuretic hormone affect renal function?

Answer 49

Antidiuretic hormone released from the posterior lobe of the pituitary gland increases water reabsorption in the renal tubules.

Question 50

Parathyroid Hormone (parathyroid gland)

Answer 50

Increases Ca++ reabsorption

Question 51

Aldosterone (adrenal gland)

Answer 51

increases sodium and water reabsorption and increases hydrogen ion secretion.

Question 52

What are diuretics?

Answer 52

Diuretics are substances that lead to decreased reabsorption of water in the kidneys, resulting in increased urine production.

Question 53

How do some diuretics like caffeine affect urine production?

Answer 53

Some diuretics like caffeine act directly on the kidneys by inhibiting water reabsorption, leading to increased urine production.

Question 54

How do other diuretics, like alcohol, affect urine production?

Answer 54

Other diuretics, such as alcohol, act indirectly by inhibiting the release of antidiuretic hormone (ADH), which leads to decreased water reabsorption in the kidneys and increased urine production.

Question 55

What is diuresis?

Answer 55

Diuresis refers to the production of urine.

Question 56

What is the common outcome of diuretic action?

Answer 56

The common outcome of diuretic action is increased urine production, which helps to eliminate excess fluids from the body.

Question 57

What is the path of urine drainage from the collecting ducts in the kidney?

Answer 57

Urine from the collecting ducts drains into a series of progressively larger ducts, including the papillary duct, minor calyx, and major calyx, before exiting the kidney via the renal pelvis.

Question 58

Where does urine collected in the renal pelvis ultimately exit the kidney?

Answer 58

Urine collected in the renal pelvis exits the kidney through the ureter.

Question 59

Describe the progression of urine drainage from the collecting ducts to the ureter.

Answer 59

Urine from the collecting ducts drains into progressively larger ducts until it reaches the renal pelvis, which then drains urine into the ureter for excretion from the kidney.

Question 60

Ureters:

Answer 60

25-30 cm long tubes that transport urine from the kidneys to the urinary bladder

Question 61

what do the ureters also serve as?

Answer 61

They can also serve as a route for pathogens into the kidneys (i.e., kidney infection)

Question 62

what is important to note about pathogens such as bacteria, that commonly entered the kidneys via the blood

Answer 62

they can also migrate via the urethra, urinary bladder, and ureters.

Question 63

where is the urinary bladder located?

Answer 63

Located in the pelvic cavity between the pubic symphysis (anteriorly) and rectum/vagina (posteriorly)

Question 64

where does the urinary bladder lie in males Vs. females?

Answer 64

In males, it lies between the pubic symphysis and rectum.

While in females, it lies between the pubic symphysis and vagina.

Question 65

What is the structure of the bladder wall?

Answer 65

The bladder wall is highly folded to allow expansion and contains layers of smooth muscle, known as the detrusor muscle.

Question 66

How many openings are there in the bladder wall?

Answer 66

There are two posterior openings and one anterior opening in the bladder wall.

Question 67

What structures open into the bladder through the ureteral openings?

Answer 67

The ureters open into the bladder through the ureteral openings.

Question 68

Where is the internal urethral orifice located?

Answer 68

located in the bladder wall

Question 69

what does the urethral orifice serve as?

Answer 69

the opening into the urethra.

Question 70

Uretral openings (2)

Answer 70

ureters

Question 71

Internal urethral orifice

Answer 71

urethra

Question 72

How many openings does the bladder wall contain for the ureters and the urethra?

Answer 72

The bladder wall contains three openings for the ureters and one opening for the urethra.

Question 73

What type of muscle is present in the bladder wall, and how is it innervated?

Answer 73

The bladder wall contains layers of smooth muscle that are innervated by the autonomic nervous system.

Question 74

What are the two sphincters that regulate the passage of urine into the urethra?

Answer 74

The internal urethral sphincter and the external urethral sphincter regulate the passage of urine into the urethra.

Question 75

Describe the internal urethral sphincter.

Answer 75

The internal urethral sphincter is a smooth muscle sphincter located around the internal urethral orifice. It is under involuntary control.

Question 76

Describe the external urethral sphincter.

Answer 76

The external urethral sphincter is a skeletal muscle sphincter within the muscles of the perineum. It is under voluntary control.

Question 77

How is the passage of urine regulated by the internal and external urethral sphincters?

Answer 77

the internal urethral sphincter, composed of smooth muscle, is under involuntary autonomic control, while the external urethral sphincter, composed of skeletal muscle, is under voluntary somatic control.

Question 78

Urethra

Answer 78

Small tube leading from the internal urethral orifice to the external environment (external urethral orifice)

Question 79

male VS. female urethra:

Answer 79

Male: passes through the penis
Female: passes through the vagina

Question 80

How does the sympathetic nervous system regulate the urinary system?

Answer 80

causes relaxation of the smooth muscle in the bladder wall and contraction of the internal urethral sphincter, preventing urination. It also induces vasoconstriction of afferent arterioles, leading to decreased urine production.

Question 81

What effect does the parasympathetic nervous system have on the urinary system?

Answer 81

The parasympathetic nervous system causes contraction of the smooth muscle in the bladder wall and relaxation of the internal urethral sphincter, resulting in urination.

Question 82

What are the functions of the urinary system?

Answer 82

“Urine Regulates Blood, Repairs Ailing People”

U - Urine production and waste elimination
R - Regulates blood ionic composition
B - Blood volume and pressure regulation
R - Regulates acid-base balance
A - Activates erythropoiesis (stimulate RBC production in bone marrow)
P - Produces active form of vitamin D

Question 83

What hormone do the kidneys secrete, and what is its function?

Answer 83

The kidneys secrete erythropoietin (EPO), which stimulates the red bone marrow to produce more red blood cells, enhancing oxygen transport in the blood.

Question 84

What is blood doping, and why do some athletes use it?

Answer 84

the practice of artificially increasing the number of red blood cells in the bloodstream to enhance athletic performance. Some athletes use exogenous erythropoietin (EPO) to achieve this, as it increases oxygen-carrying capacity.

Question 85

What are the risks associated with blood doping?

Answer 85

Blood doping carries major risks, including increased blood viscosity, which can lead to clotting, stroke, or heart failure. It has led to severe complications and even death.