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| + | {{toplink |
| + | |linkpage =WikiQuiz |
| + | |linktext = WikiQuiz |
| + | |Review= '''Mr David Kilroy''' MVB CVMA MRCVS <br> '''Tony Sarma''' BVM&S CertSAS MRCVS |
| + | }} |
| + | <br> |
| + | <WikiQuiz |
| + | questionnumber="1" |
| + | question="The lesser omentum forms between which structures?" |
| + | choice1="The lesser curvature of the stomach and the liver" |
| + | choice3="The spleen and the liver" |
| + | choice2="The stomach and the spleen" |
| + | choice4="The kidney and the spleen" |
| + | choice5="The liver and the body wall" |
| + | correctchoice="1" |
| + | feedback1="'''Correct!''' The liver forms in the ventral mesentery, which persists in adulthood as the lesser omentum. [[Monogastric Stomach - Anatomy & Physiology|WikiVet Article: lesser omentum]]." |
| + | feedback3="'''Incorrect.''' The spleen and the liver are not attached. The lesser omentum forms between the lesser curvature of the stomach and the liver. [[Monogastric Stomach - Anatomy & Physiology|WikiVet Article: Lesser omentum]]" |
| + | feedback2="'''Incorrect.''' The stomach and the spleen are attached by the gastrosplenic ligament. The lesser omentum forms between the lesser curvature of the stomach and the liver. [[Monogastric Stomach - Anatomy & Physiology|WikiVet Article: Lesser omentum]]" |
| + | feedback4="'''Incorrect.''' The kidney and the spleen are attached by the nephrosplenic ligament. The lesser omentum forms between the lesser curvature of the stomach and the liver. [[Monogastric Stomach - Anatomy & Physiology|WikiVet Article: Lesser omentum]]" |
| + | feedback5="'''Incorrect.''' The liver and the body wall are attached by the falciform ligament. The lesser omentum forms between the lesser curvature of the stomach and the liver. [[Monogastric Stomach - Anatomy & Physiology|WikiVet Article: Lesser omentum]]" |
| + | image= ""> |
| + | </WikiQuiz> |
| + | |
| + | <WikiQuiz |
| + | questionnumber="2" |
| + | question="What do enterochromaffin-like (ECL) cells, which can be found in the gastric mucosa, secrete?" |
| + | choice5="Histamine" |
| + | choice3="Hydrogen ions (H+)" |
| + | choice2="Gastrin" |
| + | choice4="Pepsinogen" |
| + | choice1="Gastric Inhibitory Peptide" |
| + | correctchoice="5" |
| + | feedback5="'''Correct!''' Enterochromaffin-like cells secrete histamine which stimulates parietal cells to secrete hydrogen ions. [[Monogastric Stomach - Anatomy & Physiology#Histology|WikiVet Article: Forestomach]]" |
| + | feedback3="'''Incorrect.''' Hydrogen ions are secreted by parietal cells in the gastric mucosa to decrease the pH in the stomach lumen which causes denaturation of ingested proteins. Enterochromaffin-like cells secrete histamine. [[Monogastric Stomach - Anatomy & Physiology#Histology|WikiVet Article: Forestomach]]" |
| + | feedback2="'''Incorrect.''' Gastrin is secreted by G-cells in the pyloric mucosa which stimulates enterochromaffin-like cells to secrete histamine. [[Monogastric Stomach - Anatomy & Physiology#Histology|WikiVet Article: Forestomach]]" |
| + | feedback4="'''Incorrect.''' Pepsinogen is secreted by chief cells in the gastric glands which is converted to its active form pepsin by hydrochloric acid in the gastric lumen.Enterochromaffin-like cells secrete histamine. [[Monogastric Stomach - Anatomy & Physiology#Histology|WikiVet Article: Forestomach]]" |
| + | feedback1="'''Incorrect.''' Gastric Inhibitory Peptide is secreted by K cells in the mucosa of the jejunum and duodenum. It acts to inhibit gastric motility and hydrochloric acid secretion in the stomach and induce insulin secretion. Enterochromaffin-like cells secrete histamine. [[Monogastric Stomach - Anatomy & Physiology#Histology|WikiVet Article: Forestomach]]" |
| + | image= ""> |
| + | </WikiQuiz> |
| + | |
| + | <WikiQuiz |
| + | questionnumber="3" |
| + | question="The falciform ligament forms between which two structures?" |
| + | choice5="The liver and the body wall" |
| + | choice4="The kidney and the spleen" |
| + | choice1="The lesser curvature of the stomach and the liver" |
| + | choice3="The stomach and the spleen" |
| + | choice2="The spleen and the liver" |
| + | correctchoice="5" |
| + | feedback5="'''Correct!''' The liver forms in the ventral mesentery. The liver remains attached to the stomach by persisting ventral mesentery known as lesser omentum and to the body wall by ventral mesentery known as the falciform ligament. Excision of the falciform ligament's attachment to the ventral body wall can greatly improve visibility of the cranial abdomen at surgery. [[Liver - Anatomy & Physiology|WikiVet Article: Falciform ligament]]" |
| + | feedback4="'''Incorrect.''' The kidney and the spleen are attached by the nephrosplenic ligament. The liver forms in the ventral mesentery. The liver remains attached to the stomach by persisting ventral mesentery known as lesser omentum and to the body wall by ventral mesentery known as the falciform ligament. Excision of the falciform ligament's attachment to the ventral body wall can greatly improve visibility of the cranial abdomen at surgery. [[Liver - Anatomy & Physiology|WikiVet Article: Falciform ligament]]" |
| + | feedback1="'''Incorrect.''' The liver forms in the ventral mesentery. The liver remains attached to the stomach by persisting ventral mesentery known as lesser omentum and to the body wall by ventral mesentery known as the falciform ligament. Excision of the falciform ligament's attachment to the ventral body wall can greatly improve visibility of the cranial abdomen at surgery. [[Liver - Anatomy & Physiology|WikiVet Article: Falciform ligament]]" |
| + | feedback3="'''Incorrect.''' The stomach and the spleen are attached by the gastrosplenic ligament. The liver forms in the ventral mesentery. The liver remains attached to the stomach by persisting ventral mesentery known as lesser omentum and to the body wall by ventral mesentery known as the falciform ligament. Excision of the falciform ligament's attachment to the ventral body wall can greatly improve visibility of the cranial abdomen at surgery. [[Liver - Anatomy & Physiology|WikiVet Article: Falciform ligament]]" |
| + | feedback2="'''Incorrect.''' The spleen and the liver are not attached. The liver forms in the ventral mesentery. The liver remains attached to the stomach by persisting ventral mesentery known as lesser omentum and to the body wall by ventral mesentery known as the falciform ligament. Excision of the falciform ligament's attachment to the ventral body wall can greatly improve visibility of the cranial abdomen at surgery. [[Liver - Anatomy & Physiology|WikiVet Article: Falciform ligament]]" |
| + | image= ""> |
| + | </WikiQuiz> |
| + | |
| + | <WikiQuiz |
| + | questionnumber="4" |
| + | question="The caudal border of which muscle forms the inguinal ligament?" |
| + | choice1="External abdominal oblique muscle" |
| + | choice2="Internal abdominal oblique muscle" |
| + | choice5="Transversus abdominis muscle" |
| + | choice3="Rectus abdominis muscle" |
| + | choice4="Cutaneous trunci muscle" |
| + | correctchoice="1" |
| + | feedback1="'''Correct!''' The caudal border of the external abdominal oblique muscle is thickened to form the inguinal ligament, and a slit in its aponeurosis forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
| + | feedback2="'''Incorrect.''' The inguinal canal is bordered cranially by the internal abdominal oblique muscle so it does not form the inguinal ligament. The caudal border of the external abdominal oblique muscle is thickened to form the inguinal ligament and a slit in its aponeurosis forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
| + | feedback5="'''Incorrect.''' The transversus abdominis muscle is not involved in the formation of the inguinal canal. The caudal border of the external abdominal oblique muscle is thickened to form the inguinal ligament and a slit in its aponeurosis forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
| + | feedback3="'''Incorrect.''' The inguinal canal is bordered medially by the lateral border of the rectus abdominis muscle so it does not form the inguinal ligament. The caudal border of the external abdominal oblique muscle is thickened to form the inguinal ligament and a slit in its aponeurosis forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
| + | feedback4="'''Incorrect.''' The cutaneous trunci muscle is not involved in the formation of the inguinal canal. The caudal border of the external abdominal oblique muscle is thickened to form the inguinal ligament and a slit in its aponeurosis forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article:Abdominal musculature]]" |
| + | image= ""> |
| + | </WikiQuiz> |
| | | |
| <WikiQuiz | | <WikiQuiz |
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| choice5="Left lateral" | | choice5="Left lateral" |
| correctchoice="3" | | correctchoice="3" |
− | feedback3="'''Correct!''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver." | + | feedback3="'''Correct!''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver.[[Liver - Anatomy & Physiology| WikiVet Article: Liver anatomy]]" |
− | feedback4="'''Incorrect.''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver." | + | feedback4="'''Incorrect.''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver. [[Liver - Anatomy & Physiology| WikiVet Article: Liver anatomy]]" |
− | feedback2="'''Incorrect.''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver." | + | feedback2="'''Incorrect.''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver. [[Liver - Anatomy & Physiology| WikiVet Article: Liver anatomy]]" |
− | feedback1="'''Incorrect.''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver." | + | feedback1="'''Incorrect.''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver. [[Liver - Anatomy & Physiology| WikiVet Article: Liver anatomy]]" |
− | feedback5="'''Incorrect.''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver." | + | feedback5="'''Incorrect.''' The hepatorenal ligament connects the cranial pole of the right kidney to the caudate lobe of the liver. [[Liver - Anatomy & Physiology| WikiVet Article: Liver anatomy]]" |
| image= ""> | | image= ""> |
| </WikiQuiz> | | </WikiQuiz> |
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| choice1="Dorsocaudally" | | choice1="Dorsocaudally" |
| correctchoice="2" | | correctchoice="2" |
− | feedback2="'''Correct!''' The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g., for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback2="'''Correct!''' The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g., for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
− | feedback4="'''Incorrect.''' The fibres of the external abdominal oblique muscle run caudoventrally from the lateral surfaces of the ribs and the lumbar fascia to the linea alba. The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g., for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback4="'''Incorrect.''' The fibres of the external abdominal oblique muscle run caudoventrally from the lateral surfaces of the ribs and the lumbar fascia to the linea alba. The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g., for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
− | feedback5="'''Incorrect.''' The fibres of the rectus abdominis muscle run craniocaudally from the ventral costal cartilages to the prepubic tendon. The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g., for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback5="'''Incorrect.''' The fibres of the rectus abdominis muscle run craniocaudally from the ventral costal cartilages to the prepubic tendon. The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g., for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
− | feedback3="'''Incorrect.''' The fibres of the transversus abdominus run dorsoventrally from the inner surface of the last ribs and the transverse processes of the lumbar vertebrae. The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g., for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback3="'''Incorrect.''' The fibres of the transversus abdominus run dorsoventrally from the inner surface of the last ribs and the transverse processes of the lumbar vertebrae. The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g., for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
− | feedback1="'''Incorrect.''' There is no abdominal muscle whose fibres run dorsocaudally. The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g. for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback1="'''Incorrect.''' There is no abdominal muscle whose fibres run dorsocaudally. The fibres of the internal abdominal oblique run cranioventrally from the tuber coxae and the thoracolumbar fascia to the linea alba. The direction of the fibres make this muscle is easily identifiable on flank laparotomy (e.g. for cat spey). [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
| image= ""> | | image= ""> |
| </WikiQuiz> | | </WikiQuiz> |
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| choice2="Cutaneous trunci muscle" | | choice2="Cutaneous trunci muscle" |
| correctchoice="3" | | correctchoice="3" |
− | feedback3="'''Correct!''' The caudal border of the external abdominal oblique muscle is thickened to form the inguinal ligament and a slit in its aponeurosis forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback3="'''Correct!''' The caudal border of the external abdominal oblique muscle is thickened to form the inguinal ligament and a slit in its aponeurosis forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
− | feedback4="'''Incorrect.''' The inguinal canal is bordered cranially by the internal abdominal oblique muscle. A slit in the aponeurosis of the external abdominal oblique muscle forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback4="'''Incorrect.''' The inguinal canal is bordered cranially by the internal abdominal oblique muscle. A slit in the aponeurosis of the external abdominal oblique muscle forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
− | feedback5="'''Incorrect.''' The transversus abdominis muscle is not involved in the formation of the inguinal canal. A slit in the aponeurosis of the external abdominal oblique muscle forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback5="'''Incorrect.''' The transversus abdominis muscle is not involved in the formation of the inguinal canal. A slit in the aponeurosis of the external abdominal oblique muscle forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
− | feedback1="'''Incorrect.''' The rectus abdominis muscle does not have an aponeurosis. A slit in the aponeurosis of the external abdominal oblique muscle forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback1="'''Incorrect.''' The rectus abdominis muscle does not have an aponeurosis. A slit in the aponeurosis of the external abdominal oblique muscle forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]]" |
− | feedback2="'''Incorrect.''' The cutaneous trunci muscle is not involved in the formation of the inguinal canal. A slit in the aponeurosis of the external abdominal oblique muscle forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: abdominal musculature]]." | + | feedback2="'''Incorrect.''' The cutaneous trunci muscle is not involved in the formation of the inguinal canal. A slit in the aponeurosis of the external abdominal oblique muscle forms the superficial inguinal ring. [[Ribs and Sternum - Anatomy & Physiology#Abdominal Musculature|WikiVet Article: Abdominal musculature]] |
| image= ""> | | image= ""> |
| </WikiQuiz> | | </WikiQuiz> |
| + | |
| | | |
| <WikiQuiz | | <WikiQuiz |
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| choice4="Duodenum" | | choice4="Duodenum" |
| correctchoice="3" | | correctchoice="3" |
− | feedback3="'''Correct!''' The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a "duodenal manoeuvre" (for the right kidney) or "colic manoeuvre" (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: retroperitoneal organs]]." | + | feedback3="'''Correct!''' The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a duodenal manoeuvre (for the right kidney) or colic manoeuvre (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal Cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: Retroperitoneal organs]]" |
− | feedback2="'''Incorrect.''' The liver is enclosed by a fold of visceral peritoneum so is intraperitoneal. The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a "duodenal manoeuvre" (for the right kidney) or "colic manoeuvre" (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: retroperitoneal organs]]." | + | feedback2="'''Incorrect.''' The liver is enclosed by a fold of visceral peritoneum so is intraperitoneal. The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a duodenal manoeuvre (for the right kidney) or colic manoeuvre (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal Cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: Retroperitoneal organs]]" |
− | feedback1="'''Incorrect.''' The pancreas is enclosed by a fold of visceral peritoneum so is intraperitoneal. The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a "duodenal manoeuvre" (for the right kidney) or "colic manoeuvre" (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: retroperitoneal organs]]." | + | feedback1="'''Incorrect.''' The pancreas is enclosed by a fold of visceral peritoneum so is intraperitoneal. The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a duodenal manoeuvre (for the right kidney) or colic manoeuvre (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal Cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: Retroperitoneal organs]]" |
− | feedback5="'''Incorrect.''' The spleen is enclosed by a fold of visceral peritoneum so is intraperitoneal. The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a "duodenal manoeuvre" (for the right kidney) or "colic manoeuvre" (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: retroperitoneal organs]]." | + | feedback5="'''Incorrect.''' The spleen is enclosed by a fold of visceral peritoneum so is intraperitoneal. The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a duodenal manoeuvre (for the right kidney) or colic manoeuvre (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal Cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: Retroperitoneal organs]]" |
− | feedback4="'''Incorrect.''' The duodenum is enclosed by a fold of visceral peritoneum so is intraperitoneal. The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a "duodenal manoeuvre" (for the right kidney) or "colic manoeuvre" (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: retroperitoneal organs]]." | + | feedback4="'''Incorrect.''' The duodenum is enclosed by a fold of visceral peritoneum so is intraperitoneal. The kidneys are located between the parietal peritoneum and the body wall, hence they are considered retroperitoneal. In practice, this means that the kidneys (and associated structures such as adrenal glands and ovaries) can be easily visualised at exploratory surgery by performing either a duodenal manoeuvre (for the right kidney) or colic manoeuvre (for the left kidney). The duodenal manoeuvre involves lifting the descending duodenum up, and moving it gently across the abdominal cavity to the left side of the body. This causes the mesoduodenum to catch the abdominal viscera and pull them to the left, allowing the right retroperitoneal space to be seen. The colic manoeuvre uses the descending colon and mesocolon similarly to see the left retroperitoneal space. [[Peritoneal Cavity - Anatomy & Physiology#Retroperitoneal Organs|WikiVet Article: Retroperitoneal organs]]" |
| image= ""> | | image= ""> |
| </WikiQuiz> | | </WikiQuiz> |
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| choice2="The greater omentum and the stomach" | | choice2="The greater omentum and the stomach" |
| correctchoice="3" | | correctchoice="3" |
− | feedback3="'''Correct!''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal cavity - Anatomy & Physiology|WikiVet Article: peritoneal cavity]]." | + | feedback3="'''Correct!''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal Cavity - Anatomy & Physiology|WikiVet Article: Peritoneal cavity]]" |
− | feedback1="'''Incorrect.''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal cavity - Anatomy & Physiology|WikiVet Article: peritoneal cavity]]." | + | feedback1="'''Incorrect.''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal Cavity - Anatomy & Physiology|WikiVet Article: Peritoneal cavity]]" |
− | feedback5="'''Incorrect.''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal cavity - Anatomy & Physiology|WikiVet Article: peritoneal cavity]]." | + | feedback5="'''Incorrect.''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal Cavity - Anatomy & Physiology|WikiVet Article: Peritoneal cavity]]" |
− | feedback4="'''Incorrect.''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal cavity - Anatomy & Physiology|WikiVet Article: peritoneal cavity]]." | + | feedback4="'''Incorrect.''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal Cavity - Anatomy & Physiology|WikiVet Article: Peritoneal cavity]]" |
− | feedback2="'''Incorrect.''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal cavity - Anatomy & Physiology|WikiVet Article: peritoneal cavity]]." | + | feedback2="'''Incorrect.''' As the stomach develops there is a great expansion of the dorsal suspension of the stomach or the greater omentum. The greater omentum is a double layer of peritoneum which attaches to the greater curvature of the stomach and the dorsal body wall. The cavity between the layers is the omental bursa and the opening to it is the epiploic foramen. [[Peritoneal Cavity - Anatomy & Physiology|WikiVet Article: Peritoneal cavity]]" |
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| </WikiQuiz> | | </WikiQuiz> |
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| choice2="Parietal peritoneum" | | choice2="Parietal peritoneum" |
| correctchoice="1" | | correctchoice="1" |
− | feedback1="'''Correct!''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: ribs and sternum]]." | + | feedback1="'''Correct!''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: Abdominal musculature]]" |
− | feedback4="'''Incorrect.''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: ribs and sternum]]." | + | feedback4="'''Incorrect.''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: Abdominal musculature]]" |
− | feedback3="'''Incorrect.''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: ribs and sternum]]." | + | feedback3="'''Incorrect.''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: Abdominal musculature]]" |
− | feedback5="'''Incorrect.''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: ribs and sternum]]." | + | feedback5="'''Incorrect.''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: Abdominal musculature]]" |
− | feedback2="'''Incorrect.''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: ribs and sternum]]." | + | feedback2="'''Incorrect.''' In a cat spay via a flank incision, the layers incised are:1) Skin 2) Subcutaneous tissue 3) 3 muscles - in order, external abdominal oblique, internal abdominal oblique and transversus abdominis 4) Parietal peritoneum. The rectus abdominis muscle is not incised during a flank incision as it lies far further ventrally. [[Ribs and Sternum - Anatomy & Physiology|WikiVet Article: Abdominal musculature]]" |
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| </WikiQuiz> | | </WikiQuiz> |
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| + | [[Category:Alimentary System Anatomy & Physiology Quizzes]] |