Difference between revisions of "Urinary Anatomy & Physiology Quiz"
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− | {{ | + | {{toplink |
+ | |linkpage =WikiQuiz | ||
+ | |linktext = WikiQuiz | ||
+ | |pagetype=Quiz | ||
+ | |Review= '''Mr David Kilroy''' MVB CVMA MRCVS <br> '''Tony Sarma''' BVM&S CertSAS MRCVS | ||
+ | |||
+ | |||
+ | }} | ||
<WikiQuiz | <WikiQuiz | ||
questionnumber="1" | questionnumber="1" | ||
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choice3="Juxtaglomerular apparatus" | choice3="Juxtaglomerular apparatus" | ||
correctchoice="2" | correctchoice="2" | ||
− | feedback2="'''Correct!''' The renal pelvis is the part of the ureter that the collecting tubules drain into, it is not part of a nephron. [[Microscopic Anatomy | + | feedback2="'''Correct!''' The renal pelvis is the part of the ureter that the collecting tubules drain into, it is not part of a nephron. [[Nephron Microscopic Anatomy |WikiVet Article: nephron]]." |
− | feedback4="'''Incorrect.''' The Bowman's capsule is the part of the nephron that, along with a glomerulus, makes up a renal corpuscle. [[Microscopic Anatomy | + | feedback4="'''Incorrect.''' The Bowman's capsule is the part of the nephron that, along with a glomerulus, makes up a renal corpuscle. [[Nephron Microscopic Anatomy |WikiVet Article: nephron]]." |
− | feedback1="'''Incorrect.''' The Loop of Henle is the part of the nephron made up of descending and ascending limbs. [[Microscopic Anatomy | + | feedback1="'''Incorrect.''' The Loop of Henle is the part of the nephron made up of descending and ascending limbs. [[Nephron Microscopic Anatomy |WikiVet Article: nephron]]." |
− | feedback5="'''Incorrect.''' The proximal convoluted tubule is the part of the nephron between the Bowman's capsule and Loop of Henle. [[Microscopic Anatomy | + | feedback5="'''Incorrect.''' The proximal convoluted tubule is the part of the nephron between the Bowman's capsule and Loop of Henle. [[Nephron Microscopic Anatomy |WikiVet Article: nephron]]." |
− | feedback3="'''Incorrect.''' The juxtaglomerular apparatus is a unique segment of the nephron where the thick ascending limb of the Loop of Henle passes between the afferent and efferent arterioles of its own glomerulus. [[Microscopic Anatomy | + | feedback3="'''Incorrect.''' The juxtaglomerular apparatus is a unique segment of the nephron where the thick ascending limb of the Loop of Henle passes between the afferent and efferent arterioles of its own glomerulus. [[Nephron Microscopic Anatomy |WikiVet Article: nephron. ]]" |
image= ""> | image= ""> | ||
</WikiQuiz> | </WikiQuiz> | ||
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choice3="Stratified squamous" | choice3="Stratified squamous" | ||
correctchoice="1" | correctchoice="1" | ||
− | feedback1="'''Correct!''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[ | + | feedback1="'''Correct!''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[Renal Anatomy - Anatomy & PhysiologyUreters - Anatomy & PhysiologyUrinary Bladder - Anatomy & Physiology|WikiVet Article:Renal pelvis, ureters, urinary bladder]]." |
− | feedback2="'''Incorrect.''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[ | + | feedback2="'''Incorrect.''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[Renal Anatomy - Anatomy & PhysiologyUreters - Anatomy & PhysiologyUrinary Bladder - Anatomy & Physiology|WikiVet Article:Renal pelvis, ureters, urinary bladder]]." |
− | feedback4="'''Incorrect.''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[ | + | feedback4="'''Incorrect.''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[Renal Anatomy - Anatomy & PhysiologyUreters - Anatomy & PhysiologyUrinary Bladder - Anatomy & Physiology|WikiVet Article:Renal pelvis, ureters, urinary bladder]]." |
− | feedback5="'''Incorrect.''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[ | + | feedback5="'''Incorrect.''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[Renal Anatomy - Anatomy & PhysiologyUreters - Anatomy & PhysiologyUrinary Bladder - Anatomy & Physiology|WikiVet Article:Renal pelvis, ureters, urinary bladder]]." |
− | feedback3="'''Incorrect.''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[ | + | feedback3="'''Incorrect.''' Transitional epithelium lines the renal pelvis, ureters and urinary bladder. [[Renal Anatomy - Anatomy & PhysiologyUreters - Anatomy & PhysiologyUrinary Bladder - Anatomy & Physiology|WikiVet Article:Renal pelvis, ureters, urinary bladder]]." |
image= ""> | image= ""> | ||
</WikiQuiz> | </WikiQuiz> | ||
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choice1="Renal pelvis" | choice1="Renal pelvis" | ||
correctchoice="5" | correctchoice="5" | ||
− | feedback5="'''Correct!''' Renal corpuscles are found in the renal cortex. [[ | + | feedback5="'''Correct!''' Renal corpuscles are found in the renal cortex. [[Renal Anatomy - Anatomy & Physiology |WikiVet Article: macroscopic renal anatomy]]." |
− | feedback3="'''Incorrect.''' The capsule is the connective tissue covering of the kidney. Renal corpuscles are present in the cortex. [[ | + | feedback3="'''Incorrect.''' The capsule is the connective tissue covering of the kidney. Renal corpuscles are present in the cortex. [[Renal Anatomy - Anatomy & Physiology|WikiVet Article: macroscopic renal anatomy]]." |
− | feedback4="'''Incorrect.''' The medulla is characterised by straight tubules, collecting ducts and a special capillary network, the vasa recta. Renal corpuscles are present in the cortex. [[ | + | feedback4="'''Incorrect.''' The medulla is characterised by straight tubules, collecting ducts and a special capillary network, the vasa recta. Renal corpuscles are present in the cortex. [[Renal Anatomy - Anatomy & Physiology|WikiVet Article: macroscopic renal anatomy]]." |
− | feedback2="'''Incorrect.''' The medulla is characterised by straight tubules, collecting ducts and a special capillary network, the vasa recta. Renal corpuscles are present in the cortex. [[ | + | feedback2="'''Incorrect.''' The medulla is characterised by straight tubules, collecting ducts and a special capillary network, the vasa recta. Renal corpuscles are present in the cortex. [[Renal Anatomy - Anatomy & Physiology|WikiVet Article: macroscopic renal anatomy. ]]" |
− | feedback1="'''Incorrect.''' The renal pelvis is a dilation of the proximal end of the ureter into which the collecting ducts open and urine drains. Renal corpuscles are present in the cortex. [[ | + | feedback1="'''Incorrect.''' The renal pelvis is a dilation of the proximal end of the ureter into which the collecting ducts open and urine drains. Renal corpuscles are present in the cortex. [[Renal Anatomy - Anatomy & Physiology|WikiVet Article: macroscopic renal anatomy]]." |
image= ""> | image= ""> | ||
</WikiQuiz> | </WikiQuiz> | ||
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choice1="Aorta, renal artery, interlobar artery, interlobular artery, afferent arteriole, glomerulus, interlobular artery." | choice1="Aorta, renal artery, interlobar artery, interlobular artery, afferent arteriole, glomerulus, interlobular artery." | ||
correctchoice="4" | correctchoice="4" | ||
− | feedback4="'''Correct!''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. [[ | + | feedback4="'''Correct!''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. [[Renal Anatomy - Anatomy & Physiology|WikiVet Article:Renal blood supply]]." |
− | feedback5="'''Incorrect.''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. The internal iliac artery gives rise to the internal pudendal artery. [[ | + | feedback5="'''Incorrect.''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. The internal iliac artery gives rise to the internal pudendal artery. [[Renal Anatomy - Anatomy & Physiology|WikiVet Article:Renal blood supply]]." |
− | feedback3="'''Incorrect.''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. [[ | + | feedback3="'''Incorrect.''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. [[Renal Anatomy - Anatomy & Physiology|WikiVet Article:Renal blood supply]]." |
− | feedback2="'''Incorrect.''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. [[ | + | feedback2="'''Incorrect.''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. [[Renal Anatomy - Anatomy & Physiology|WikiVet Article:Renal blood supply]]." |
− | feedback1="'''Incorrect.''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. [[ | + | feedback1="'''Incorrect.''' Each kidney is supplied by a renal artery, a branch of the abdominal aorta. The renal artery divides into several interlobar arteries. These give rise to arcuate arteries at the corticomedullary junction. These in turn give origin to numerous interlobular arteries that supply the lobules into which the cortex is divided. Each interlobular artery gives rise to many branches (afferent arterioles) that supply individual glomeruli. [[Renal Anatomy - Anatomy & Physiology|WikiVet Article:Renal blood supply]]." |
image= ""> | image= ""> | ||
</WikiQuiz> | </WikiQuiz> | ||
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choice4="Thalamus" | choice4="Thalamus" | ||
correctchoice="5" | correctchoice="5" | ||
− | feedback5="'''Correct!''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[ | + | feedback5="'''Correct!''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[Micturition - Anatomy & Physiology|WikiVet Article: pons]]." |
− | feedback1="'''Incorrect.''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[ | + | feedback1="'''Incorrect.''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[Micturition - Anatomy & Physiology|WikiVet Article: pons]]." |
− | feedback2="'''Incorrect.''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[ | + | feedback2="'''Incorrect.''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[Micturition - Anatomy & Physiology|WikiVet Article: pons]]." |
− | feedback3="'''Incorrect.''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[ | + | feedback3="'''Incorrect.''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[Micturition - Anatomy & Physiology|WikiVet Article: pons]]." |
− | feedback4="'''Incorrect.''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[ | + | feedback4="'''Incorrect.''' The micturition centre is located in the pons. It responds to sensory information from bladder stretch receptors by co-ordinating relaxation of the urethralis muscle along with detrusor contraction to produce emptying of the bladder. [[Micturition - Anatomy & Physiology|WikiVet Article: pons]]." |
image= ""> | image= ""> | ||
</WikiQuiz> | </WikiQuiz> | ||
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choice2="The detrusor muscle is relaxed." | choice2="The detrusor muscle is relaxed." | ||
correctchoice="5" | correctchoice="5" | ||
− | feedback5="'''Correct!''' The parasympathetic nervous system is dominant in the emptying phase which requires contraction of the detrusor muscle and inhibition of the pudendal nerve, thus causing relaxation of the urethralis muscle. [[ | + | feedback5="'''Correct!''' The parasympathetic nervous system is dominant in the emptying phase which requires contraction of the detrusor muscle and inhibition of the pudendal nerve, thus causing relaxation of the urethralis muscle. [[Micturition - Anatomy & Physiology|WikiVet Article: parasympathetic dominance. ]]" |
− | feedback4="'''Incorrect.''' This occurs during the storage phase when the sympathetic nervous system is dominant. When the parasympathetic nervous system is dominant there is contraction of the detrusor muscle and inhibition of the pudendal nerve. [[ | + | feedback4="'''Incorrect.''' This occurs during the storage phase when the sympathetic nervous system is dominant. When the parasympathetic nervous system is dominant there is contraction of the detrusor muscle and inhibition of the pudendal nerve. [[Micturition - Anatomy & Physiology|WikiVet Article: parasympathetic dominance. ]]" |
− | feedback1="'''Incorrect.''' This occurs during the storage phase when the sympathetic nervous system is dominant. When the parasympathetic nervous system is dominant there is contraction of the detrusor muscle and inhibition of the pudendal nerve. [[ | + | feedback1="'''Incorrect.''' This occurs during the storage phase when the sympathetic nervous system is dominant. When the parasympathetic nervous system is dominant there is contraction of the detrusor muscle and inhibition of the pudendal nerve. [[Micturition - Anatomy & Physiology|WikiVet Article: parasympathetic dominance. ]]" |
− | feedback3="'''Incorrect.''' This occurs during the storage phase when the sympathetic nervous system is dominant. When the parasympathetic nervous system is dominant there is contraction of the detrusor muscle and inhibition of the pudendal nerve. [[ | + | feedback3="'''Incorrect.''' This occurs during the storage phase when the sympathetic nervous system is dominant. When the parasympathetic nervous system is dominant there is contraction of the detrusor muscle and inhibition of the pudendal nerve. [[Micturition - Anatomy & Physiology|WikiVet Article: parasympathetic dominance]]." |
− | feedback2="'''Incorrect.''' This occurs during the storage phase when the sympathetic nervous system is dominant. When the parasympathetic nervous system is dominant there is contraction of the detrusor muscle and inhibition of the pudendal nerve. [[ | + | feedback2="'''Incorrect.''' This occurs during the storage phase when the sympathetic nervous system is dominant. When the parasympathetic nervous system is dominant there is contraction of the detrusor muscle and inhibition of the pudendal nerve. [[Micturition - Anatomy & Physiology|WikiVet Article: parasympathetic dominance. ]]" |
image= ""> | image= ""> | ||
</WikiQuiz> | </WikiQuiz> | ||
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choice3="GFR is the fluid filtered from the glomeruli into Bowman's space, plus the fluid secreted into the nephron, minus the fluid reabsorbed from the nephron into the peritubular capillary network." | choice3="GFR is the fluid filtered from the glomeruli into Bowman's space, plus the fluid secreted into the nephron, minus the fluid reabsorbed from the nephron into the peritubular capillary network." | ||
correctchoice="4" | correctchoice="4" | ||
− | feedback4="'''Correct!''' The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[ | + | feedback4="'''Correct!''' The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR]]." |
− | feedback5="'''Incorrect.''' The volume of fluid flowing through the glomerulus per unit time is the rate of blood flow through the glomerulus. The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[ | + | feedback5="'''Incorrect.''' The volume of fluid flowing through the glomerulus per unit time is the rate of blood flow through the glomerulus. The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR]]." |
− | feedback1="'''Incorrect.''' The direction of fluid flow is from the glomeruli into Bowman's space. The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[ | + | feedback1="'''Incorrect.''' The direction of fluid flow is from the glomeruli into Bowman's space. The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR. ]]" |
− | feedback2="'''Incorrect.''' The volume of fluid excreted by the kidney per unit time is the urine flow rate. The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[ | + | feedback2="'''Incorrect.''' The volume of fluid excreted by the kidney per unit time is the urine flow rate. The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR]]." |
− | feedback3="'''Incorrect.''' The fluid filtered from the glomeruli into Bowman's space, plus the fluid secreted into the nephron, minus the fluid reabsorbed from the nephron into the peritubular capillary network is the volume of fluid excreted by the kidney. The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[ | + | feedback3="'''Incorrect.''' The fluid filtered from the glomeruli into Bowman's space, plus the fluid secreted into the nephron, minus the fluid reabsorbed from the nephron into the peritubular capillary network is the volume of fluid excreted by the kidney. The GFR is the volume of fluid filtered from the glomeruli into the Bowman's space per unit time. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR]]." |
image= ""> | image= ""> | ||
</WikiQuiz> | </WikiQuiz> | ||
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choice3="There is a large amount of protein reabsorbed in the nephron." | choice3="There is a large amount of protein reabsorbed in the nephron." | ||
correctchoice="1" | correctchoice="1" | ||
− | feedback1="'''Correct!''' Most proteins are too large to be filtered and therefore remain in the glomerular capillary. Large proteins are not filtered into Bowman's capsule unless a component of the filtration barrier (e.g. the glomerular basement membrane) is damaged. [[ | + | feedback1="'''Correct!''' Most proteins are too large to be filtered and therefore remain in the glomerular capillary. Large proteins are not filtered into Bowman's capsule unless a component of the filtration barrier (e.g. the glomerular basement membrane) is damaged. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Glomerular Filtration |WikiVet Article: glomerular filtration]]." |
− | feedback2="'''Incorrect.''' Most proteins are too large to be filtered and therefore remain in the glomerular capillary. Large proteins are not filtered into Bowman's capsule unless a component of the filtration barrier (e.g. the glomerular basement membrane) is damaged in which case the oncotic pressure would be higher than zero. Oncotic pressure in the Bowman's capsule is normally zero because filtered fluid is essentially protein free. [[ | + | feedback2="'''Incorrect.''' Most proteins are too large to be filtered and therefore remain in the glomerular capillary. Large proteins are not filtered into Bowman's capsule unless a component of the filtration barrier (e.g. the glomerular basement membrane) is damaged in which case the oncotic pressure would be higher than zero. Oncotic pressure in the Bowman's capsule is normally zero because filtered fluid is essentially protein free. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Glomerular Filtration|WikiVet Article: glomerular filtration]]." |
− | feedback5="'''Incorrect.''' There is high hydrostatic pressure in the capillaries causing filtration into the Bowman's space because there is low hydrostatic pressure in the Bowman's space. Oncotic pressure in the Bowman's capsule is normally zero because filtered fluid is essentially protein free. [[ | + | feedback5="'''Incorrect.''' There is high hydrostatic pressure in the capillaries causing filtration into the Bowman's space because there is low hydrostatic pressure in the Bowman's space. Oncotic pressure in the Bowman's capsule is normally zero because filtered fluid is essentially protein free. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Glomerular Filtration|WikiVet Article: glomerular filtration]]." |
− | feedback4="'''Incorrect.''' Hydrostatic pressure does not directly affect oncotic pressure. Most proteins are too large to be filtered and therefore remain in the glomerular capillary. Large proteins are not filtered into Bowman's capsule unless a component of the filtration barrier (e.g. the glomerular basement membrane) is damaged. Oncotic pressure in the Bowman's capsule is normally zero because filtered fluid is essentially protein free. [[ | + | feedback4="'''Incorrect.''' Hydrostatic pressure does not directly affect oncotic pressure. Most proteins are too large to be filtered and therefore remain in the glomerular capillary. Large proteins are not filtered into Bowman's capsule unless a component of the filtration barrier (e.g. the glomerular basement membrane) is damaged. Oncotic pressure in the Bowman's capsule is normally zero because filtered fluid is essentially protein free. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Glomerular Filtration|WikiVet Article: glomerular filtration]]." |
− | feedback3="'''Incorrect.''' Large amounts of protein are not capable of being reabsorbed from the nephron back into the blood. Most proteins are too large to be filtered and therefore remain in the glomerular capillary. Large proteins are not filtered into Bowman's capsule unless a component of the filtration barrier (e.g. the glomerular basement membrane) is damaged. Oncotic pressure in the Bowman's capsule is normally zero because filtered fluid is essentially protein free. [[ | + | feedback3="'''Incorrect.''' Large amounts of protein are not capable of being reabsorbed from the nephron back into the blood. Most proteins are too large to be filtered and therefore remain in the glomerular capillary. Large proteins are not filtered into Bowman's capsule unless a component of the filtration barrier (e.g. the glomerular basement membrane) is damaged. Oncotic pressure in the Bowman's capsule is normally zero because filtered fluid is essentially protein free. [[Glomerular Apparatus and Filtration - Anatomy & Physiology#Glomerular Filtration|WikiVet Article: glomerular filtration]]." |
image= ""> | image= ""> | ||
</WikiQuiz> | </WikiQuiz> | ||
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feedback3="'''Incorrect.''' All major hormonal controls of reabsorption are exerted on the late distal convoluted tubule and the collecting ducts. [[Aldosterone#Aldosterone|WikiVet Article:Aldosterone]]." | feedback3="'''Incorrect.''' All major hormonal controls of reabsorption are exerted on the late distal convoluted tubule and the collecting ducts. [[Aldosterone#Aldosterone|WikiVet Article:Aldosterone]]." | ||
feedback2="'''Incorrect.''' All major hormonal controls of reabsorption are exerted on the collecting ducts. [[Aldosterone#Aldosterone|WikiVet Article:Aldosterone]]." | feedback2="'''Incorrect.''' All major hormonal controls of reabsorption are exerted on the collecting ducts. [[Aldosterone#Aldosterone|WikiVet Article:Aldosterone]]." | ||
− | feedback1="'''Incorrect.''' All major hormonal controls of reabsorption are exerted on the late distal convoluted tubule and the collecting ducts. [[Aldosterone#Aldosterone|WikiVet Article: | + | feedback1="'''Incorrect.''' All major hormonal controls of reabsorption are exerted on the late distal convoluted tubule and the collecting ducts. [[Aldosterone#Aldosterone|WikiVet Article:Aldosterone]]." |
feedback5="'''Incorrect.''' All major hormonal controls of reabsorption are exerted on the late distal convoluted tubule and the collecting ducts. [[Aldosterone#Aldosterone|WikiVet Article:Aldosterone]]." | feedback5="'''Incorrect.''' All major hormonal controls of reabsorption are exerted on the late distal convoluted tubule and the collecting ducts. [[Aldosterone#Aldosterone|WikiVet Article:Aldosterone]]." | ||
image= ""> | image= ""> | ||
</WikiQuiz> | </WikiQuiz> | ||
+ | |||
+ | [[Category:Urinary System Anatomy & Physiology Quizzes]] |
Latest revision as of 11:04, 26 June 2011
|
Questions reviewed by: | Mr David Kilroy MVB CVMA MRCVS Tony Sarma BVM&S CertSAS MRCVS |
1 |
Which of the following structures is NOT a segment of a nephron? |
2 |
What type of epithelium lines the renal pelvis, ureters and urinary bladder? |
3 |
Renal corpuscles are present in which part of the kidney's structure? |
4 |
On which section of the nephron does aldosterone act to stimulate sodium reabsorption? |
5 |
What is the sequence of blood vessels supplying the kidney? |
6 |
Where is the micturition centre located? |
7 |
What happens during the phase of micturition when the parasympathetic nervous system is dominant? |
8 |
The role of the juxtaglomerular apparatus in the kidney is to synthesise and secrete which enzyme? |
9 |
What is the glomerular filtration rate (GFR)? |
10 |
The descending limb of the loop of Henle is freely permeable to which substance(s)? |
11 |
Why is the oncotic pressure in the Bowman's space normally zero? |
12 |
In which segment(s) of the nephron is most of the filtered sodium, chloride and potassium ions reabsorbed? |
13 |
On which section(s) of the nephron does aldosterone act to stimulate sodium reabsorption? |