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Text replace - "[[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology" to "[[Glomerular Apparatus and Filtration - Anatomy & Physiology"
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR]]."
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR]]."
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR. ]]"
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR]]."
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Physiological Regulators of GFR|WikiVet Article: GFR]]."
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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]]."
 
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Glomerular Filtration |WikiVet Article: glomerular filtration]]."
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Glomerular Filtration|WikiVet Article: glomerular filtration]]."
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Glomerular Filtration|WikiVet Article: glomerular filtration]]."
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Glomerular Filtration|WikiVet Article: glomerular filtration]]."
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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. [[The Formation of the Filtrate by the Glomerular Apparatus- Anatomy & Physiology#Glomerular Filtration|WikiVet Article: glomerular filtration]]."
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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]]."
 
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</WikiQuiz>
 
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