Difference between revisions of "Alimentary System - Horse Anatomy"

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==Introduction==
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The horse is a monogastric hindgut fermenter. The horse evolved for grazing and it does so for up to 17 hours a day. A high proportion of the horse's dietary carbohydrate is in the form of '''starch'''. A mature horse eats 2-2.5% of it's body weight in dry matter every day, 1.5-1.75% of this should be fibre (hay/haylage). This is to prevent a rapid drop in pH in the large intestine and also to stimulate peristalsis in the gut and prevent build up of gas.
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==Oral Cavity==
 
==Oral Cavity==
===Teeth===
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===[[Teeth - Anatomy & Physiology|Teeth]]===
[[Image:Horse teeth.jpg|thumb|right|150px|Tooth identifation in the horse- copyright Academy of Equine Dentistry-2008]]
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[[Image:Horse teeth.jpg|thumb|right|200px|Tooth identifation in the horse - © Academy of Equine Dentistry-2008]]
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[[Image:Horse Tooth.jpg|thumb|right|200px|Horse tooth - © Malcom Morley]]
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'''Dental Formula'''
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:The formula for '''deciduous''' teeth: 2 (I3/3 C0/0 P3/3) 
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:The formula for '''permanent''' teeth: 2 (I3/3 C1/1 P3-4/3 M3/3) 
  
====Dental Formula====
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'''Canines'''
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:The canines are '''rudimentary''' and are located in the '''diastema'''. The size of the [[Tooth - Anatomy & Physiology#Root|root]] is proportionally larger than  the [[Tooth - Anatomy & Physiology#Crown|crown]].
  
The formula for '''deciduous''' teeth: 2 (I3/3 C0/0 P3/3) 
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'''Molars'''
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:The molars have enlarged surfaces and higher [[Tooth - Anatomy & Physiology#Crown|crowns]]. They have delayed [[Tooth - Anatomy & Physiology#Root|root]] development and complicated folding of [[Tooth - Anatomy & Physiology#Enamel|enamel]].
  
The formula for '''permanent''' teeth: 2 (I3/3 C1/1 P3-4/3 M3/3) 
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'''Incisors'''
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:Incisors have high [[Tooth - Anatomy & Physiology#Crown|crowns]] and folded [[Tooth - Anatomy & Physiology#Enamel|enamel]] surfaces. Their [[Tooth - Anatomy & Physiology#Root|roots]] converge.
  
====Canines====
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'''Premolars'''
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:A horse's '''Wolf tooth''' (PM1) is often lacking. Molars and Premolars form a continuous surface. The cheek teeth have a high rate of wear and continually erupt. The upper teeth are wider than the lower. There is no infundibulum in the lower teeth.
  
The canines are '''rudimentary''' and in '''diastema'''. The size of the [[Enamel Organ#Root|root]] is proportionally larger than  the [[Enamel Organ#Crown|crown]].
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====Ageing====
  
====Molars====
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Horses can be aged by their teeth. At two and a half years of age the first permanent incisor will erupt; at three and a half the second permanent incisor will erupt and at four and a half the third permanent incisor will erupt. Over five years of age the folding of the enamel ring ('''infundibulum''') can indicate age. There is a seven year hook and over 13 years of age a '''dental star''' will be present.
[[Image:Horse Tooth.jpg|thumb|right|150px|Horse tooth - Copyright Malcom Morley]]
 
  
The molars have enlarged surfaces and higher [[Enamel Organ#Crown|crowns]]. They have delayed [[Enamel Organ#Root|root]] development and complicated folding of [[Enamel Organ#Enamel|enamel]].
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The '''Galvayne's Groove''' is a brown groove on the upper corner incisor teeth and indicates that the horse is over 10 years old. At 15 the groove will be approximately half way down the tooth; At 20 the groove will run down the whole tooth; Over 20 the groove begins to disappear; At 25 the groove will only be visible on the bottom half of the tooth. At 30 the groove will usually be gone.
  
====Incisors====
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===Palate===
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Horses have a tight laryngeal cuff around the laryngeal entrance, therefore the [[Soft Palate|soft palate]] cannot be raised for long periods of time. This causes them to be obligate nasal breathers. Laryngeal cuffing also prevents [[Vomiting|vomiting]]. There are no specific species diferences in the [[Hard Palate|hard palate]].
  
Incisors have high [[Enamel Organ#Crown|crowns]] and folded [[Enamel Organ#Enamel|enamel]] surfaces. Their [[Enamel Organ#Root|roots]] converge.
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==[[Oesophagus - Anatomy & Physiology|Oesophagus]]==
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In the horse, the oesophageal lumen narrows at the thoracic inlet and oesophageal hiatus of the diaphragm; this predisposes them to impaction (choke). Another factor specific to horses is that striated muscle exists only in the rostral 65% of the oesophagus.
  
====Premolars====
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==Stomach==
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[[Image:Margo Plicatus.jpg|thumb|right|250px|Equine Stomach with Margo Plicatus - © RVC 2008]]
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The horse has a [[Monogastric Stomach - Anatomy & Physiology|monogastric stomach]] located on the left side of the abdomen. A region called the '''margo plicatus''' is present which separates the glandular and non-glandular parts of the equine stomach. The non-glandular area is lined with squamous epithelium (not columnar).
  
A horse's '''Wolf tooth''' (PM1) is often lacking. Molars and Premolars form a continuous surface. Premolars have a high rate of wear and continually erupt. The upper teeth are wider than the lower. There is no infundibulum in the lower teeth.
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The stomach is relatively small (10% GIT) and its capacity is 8-16 litres. The equine stomach is rarely empty, retention time is short and expulsion into the [[Duodenum - Anatomy & Physiology|duodenum]] stops when feeding stops. Although fluid exits quickly, feed particles can be retained for more than 48 hours as digestion is initiated in the stomach. A 500kg horse can produce 30 litres of gastric juice in 24 hours. The strong '''cardiac sphincter''' allows movement of gas and fluid into the stomach, but not out of it. This prevents the animal from [[Vomiting|vomiting]]. Therefore, any disorder that results in aboral fluid movement from the small intestine results in fluid accumulation in the stomach (gastric reflux), [[Gastric Dilation and Rupture - Horse|dilation and eventually gastric rupture]] if left untreated.
  
====Ageing====
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==[[Small Intestine Overview - Anatomy & Physiology|Small Intestine]]==
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===Duodenum===
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[[Image:Section of duodenum from horse.JPG|thumb|right|250px|Section of equine duodenum- © RVC 2008]]
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The descending duodenum is dorsal on the right side of the abdomen, suspended from the dorsal body wall by the mesoduodenum. The mesoduodenum is relatively short, so the duodenum is closely tethered in a constant position. In the right paralumbar fossa region, the descending duodenum turns towards the midline and is attached to the base of the [[Caecum - Anatomy & Physiology|caecum]]. The descending duodenum then runs caudally beneath the [[Liver - Anatomy & Physiology|liver]] to the caudal pole of the right kidney where it has its caudal flexure to become the ascending duodenum.
  
Horses can be aged by their teeth. At 2 and a half the first permanent incisor will erupt; At 3 and a half the second permanent incisor will erupt and at 4 and a half the third permanent incisor will erupt. Over 5 years of age the folding of the enamel ring ('''infundibulum''') can indicate age. There is a 7 year hook and over 13 years of age a '''dental star''' will be present.
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===Jejunum===
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The jejunum is confined to the left dorsal part of the abdomen associated with a long mesentery. It is restricted to this position by the large [[Caecum - Anatomy & Physiology|caecum]] on the right, and ascending [[Colon - Anatomy & Physiology|colon]] ventrally on both sides.
  
The '''Galvayne's Groove''' is a brown groove on the upper corner incisor teeth and indicates that the horse is over 10 years old. At 15 the groove will be approximately half way down the tooth; At 20 the groove will run down the whole tooth; Over 20 the grove begins to disappear; At 25 the groove will only be visible on the bottom half of the tooth. At 30 the groove will usually be gone.
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===Ileum===
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The terminal portion of the small intestine is the ileum, which joins the caecum at its dorso-medial aspect. The ileal mesentery attaches to the [[Caecum - Anatomy & Physiology|caecum]] at the dorsal caecal band.
  
===Palate===
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==[[Large Intestine Overview - Anatomy & Physiology|Large Intestine]]==
==Oesophagus==
 
==Stomach==
 
A region called the '''margo plicatus''' is present which separates the glandular and non-glandular parts of the equine stomach. The non-glandular area is lined with squamous epithelium (not columnar).
 
The stomach is relatively small (10% GIT) with a strong '''cardiac sphincter''' which prevents the animal from [[Vomiting|vomiting]]. The equine stomach is rarely empty, retention time is short and expulsion into the [[Duodenum - Anatomy & Physiology|duodenum]] stops when feeding stops. A 500kg horse can produce 30l of gastric juice in 24 hours.
 
[[Image:Margo Plicatus.jpg|thumb|right|250px|Equine Stomch with Margo Plicatus - Copyright RVC 2008]]
 
 
 
==Small Intestine==
 
==Large Intestine==
 
===Introduction===
 
The horse is a monagastric hindgut fermenter. The horse evolved for grazing and it does so for up to 17 hours a day. A high proportion of the horse's dietary carbohydrate is in the form of '''starch'''. A mature horse eats 2-2.5% of it's body weight in dry matter every day, 1.5-1.75% of this should be fibre (hay/haylage). This is to prevent a rapid drop in pH in the large intestine and also to stimulate peristalsis in the gut and prevent build up of gas.
 
  
Undigested material spends a long time in the [[Caecum - Anatomy & Physiology|caecum]] and [[Large Intestine - Anatomy & Physiology|large intestine]] being digested by microbial fermentation, mainly cellulose (95% after 65 hours).  
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Undigested material spends a long time in the [[Caecum - Anatomy & Physiology|caecum]] and [[Large Intestine - Anatomy & Physiology|large intestine]] undergoing microbial fermentation, mainly of cellulose (95% after 65 hours).  
  
In the hindgut of the horse; 75-85% of insoluble carbohydrates is digested, 15-30% of soluble carbohydrates and 30% of protein digestion. A lot of absorption of [[Volatile Fatty Acids|volatile fatty acids (VFAs)]] and water occurs in the large intestine which pass readily into the blood. Electrolytes are also absorbed in the large intestine; 95% of sodium and chloride and 75% of potassium and phosphate.
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In the hindgut of the horse; 75-85% of insoluble carbohydrates is digested, 15-30% of soluble carbohydrates and 30% of protein is digested. A lot of absorption of [[Volatile Fatty Acids|volatile fatty acids (VFAs)]] and water occurs in the large intestine which pass readily into the blood. Electrolytes are also absorbed in the large intestine; 95% of sodium and chloride and 75% of potassium and phosphate.
 
To mix the contents of the large intestines, the taenia and circular muscle of the tunica muscularis contract. This also transports the ingesta through the large intestine and brings the products of fermentation in contact with the epithelium.
 
To mix the contents of the large intestines, the taenia and circular muscle of the tunica muscularis contract. This also transports the ingesta through the large intestine and brings the products of fermentation in contact with the epithelium.
  
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The ileum opens into the caecum at the '''ileal papilla'''. This is a small projection into the caecum housing the ileal sphincter and venous plexus that, together, control the ileal orifice.
 
The ileum opens into the caecum at the '''ileal papilla'''. This is a small projection into the caecum housing the ileal sphincter and venous plexus that, together, control the ileal orifice.
  
'''Taenia''' are present. Taenia are formed by concentration of the ''longitudinal'' muscle layer. Between the taenia are sacculations, or '''haustra'''. Haustra appear as folds on the interior surface. There are '''four''' taenia over the [[Caecum - Anatomy & Physiology|caecum]]; dorsal, ventral, lateral and medial. The '''dorsal''' taenia provides the attachment site for the ileocaecal fold, which joins the caecum to the [[Ileum - Anatomy & Physiology|ileum]].
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'''Taeniae''' are present. Taeniae are formed by concentration of the ''longitudinal'' muscle layer. Between the taeniae are sacculations, or '''haustra'''. Haustra appear as folds on the interior surface. There are '''four''' taeniae over the [[Caecum - Anatomy & Physiology|caecum]]; dorsal, ventral, lateral and medial. The '''dorsal''' taenia provides the attachment site for the ileocaecal fold, which joins the caecum to the [[Ileum - Anatomy & Physiology|ileum]].
  
 
The '''lateral''' taenia provides the attachment site for the caecocolic fold, which joins the caecum to the ascending [[Colon - Anatomy & Physiology|colon]]. The '''ventral''' taenia is free.
 
The '''lateral''' taenia provides the attachment site for the caecocolic fold, which joins the caecum to the ascending [[Colon - Anatomy & Physiology|colon]]. The '''ventral''' taenia is free.
  
The '''medial''' and '''lateral''' taenia are where the caecal vessels and [[Lymph Nodes - Anatomy & Physiology|lymph nodes]] are located. Ingesta is regularly transported from the [[Ileum - Anatomy & Physiology|ileum]] to the [[Caecum - Anatomy & Physiology|caecum]], this movement can be heard upon auscultation of the right dorsal quadrant of the caudal abdomen.
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The '''medial''' and '''lateral''' taeniae are where the caecal vessels and [[Lymph Nodes - Anatomy & Physiology|lymph nodes]] are located. Ingesta is regularly transported from the [[Ileum - Anatomy & Physiology|ileum]] to the [[Caecum - Anatomy & Physiology|caecum]], this movement can be heard upon auscultation of the right dorsal quadrant of the caudal abdomen.
Ausculatation of this area is carried out in the assesment of colic. In the horse, the [[Caecum - Anatomy & Physiology|caecum]] is responsible for the digestion of complex carbohydrates such as cellulose.
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[[Colic Diagnosis - Abdominal Auscultation|Ausculatation of this area]] is carried out in the assessment of [[:Category:Colic in Horses|colic]]. In the horse, the [[Caecum - Anatomy & Physiology|caecum]] is responsible for the digestion of complex carbohydrates such as cellulose.
  
 
===[[Colon - Anatomy & Physiology|Colon]]===
 
===[[Colon - Anatomy & Physiology|Colon]]===
  
====Ascending colon====
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====Ascending Colon====
 
The ascending colon is very large and takes up most of the ventral abdomen. It is the shape of a double "U", where one "U" is on top of the other. There are four limbs that lie parallel to each other, and three flexures that change these direction of the limbs.  
 
The ascending colon is very large and takes up most of the ventral abdomen. It is the shape of a double "U", where one "U" is on top of the other. There are four limbs that lie parallel to each other, and three flexures that change these direction of the limbs.  
  
 
The sequence of the limbs and flexures of the ascending colon is as follows; '''Right Ventral Colon''' ''(for those with an RVC bias remember, "the RVC comes first!")'', passes out of the caecocolic orifice on the right side of the abdomen and continues cranially to the xiphoid region; '''Sternal Flexure''', passes across the midline from right to left, '''Left Ventral Colon''', runs caudally on the left ventral abdominal floor; '''Pelvic Flexure''', turns dorsally just cranial to the pelvic inlet and then runs cranially to the diaphragm, '''Left Dorsal Colon''', runs cranially, parallel and dorsal to the left ventral colon; '''Diaphragmatic Flexure''', turns caudally at the diaphragm; '''Right Dorsal Colon''', continues caudally on the right. It is the shortest limb of the ascending colon.
 
The sequence of the limbs and flexures of the ascending colon is as follows; '''Right Ventral Colon''' ''(for those with an RVC bias remember, "the RVC comes first!")'', passes out of the caecocolic orifice on the right side of the abdomen and continues cranially to the xiphoid region; '''Sternal Flexure''', passes across the midline from right to left, '''Left Ventral Colon''', runs caudally on the left ventral abdominal floor; '''Pelvic Flexure''', turns dorsally just cranial to the pelvic inlet and then runs cranially to the diaphragm, '''Left Dorsal Colon''', runs cranially, parallel and dorsal to the left ventral colon; '''Diaphragmatic Flexure''', turns caudally at the diaphragm; '''Right Dorsal Colon''', continues caudally on the right. It is the shortest limb of the ascending colon.
  
The '''transverse colon''' continues on from the right dorsal colon as the right dorsal colon turns medially. The right dorsal colon is attached by a mesentery to the dorsal abdominal wall, the base of the [[Caecum - Anatomy & Physiology|caecum]], the root of the mesentry and the [[Pancreas - Anatomy & Physiology|pancreas]]. This anatomical arrangement of mesentery allows the left ascending colon to twist and is a common cause of colic ([[Large Colon Torsion - Horse|colonic torsion]]).  
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The '''transverse colon''' continues on from the right dorsal colon as the right dorsal colon turns medially. The right dorsal colon is attached by a mesentery to the dorsal abdominal wall, the base of the [[Caecum - Anatomy & Physiology|caecum]], the root of the mesentery and the [[Pancreas - Anatomy & Physiology|pancreas]]. This anatomical arrangement of mesentery allows the left ascending colon to twist and is a common cause of [[:Category:Colic in Horses|colic]] ([[Large Colon Torsion - Horse|colonic torsion]]).  
  
The ventral parts of the ascending colon are attached to the dorsal parts by a short '''mesocolon'''. The mesocolon houses the blood vessels, nerves and lymphatics. In the ventral colon many important digestive and absorptive functions take place, whilst the dorsal colon is mainly responsible for transportation of ingesta. '''Taenia''' are present. Different parts of the colon can be distinguished by the number of taenia present:
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The ventral parts of the ascending colon are attached to the dorsal parts by a short '''mesocolon'''. The mesocolon houses the blood vessels, nerves and lymphatics. In the ventral colon many important digestive and absorptive functions take place, whilst the dorsal colon is mainly responsible for transportation of ingesta. '''Taeniae''' are present. Different parts of the colon can be distinguished by the number of taeniae present:
  
The right and left ventral colon and the sternal flexure have '''four''' taenia. The left dorsal colon and pelvic flexure have '''one''' taenia and the right dorsal colon and diaphragmatic flexure have '''three''' taenia.
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The right and left ventral colon and the sternal flexure have '''four''' taeniae. The left dorsal colon and pelvic flexure have '''one''' taenia and the right dorsal colon and diaphragmatic flexure have '''three''' taeniae.
  
 
====Transverse Colon====
 
====Transverse Colon====
  
The transverse colon is short. It passes from across the midline from right to left. It passes cranial to the root of the mesentery  
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The transverse colon is short. It passes from across the midline from right to left. It passes cranial to the root of the mesentery. It has '''two''' taeniae. It turns caudally to become the descending colon at the level of the [[Urinary System Overview - Anatomy & Physiology|left kidney]].
The transverse colon has '''two''' taenia. It turns caudally to become the descending colon at the level of the [[Urinary System Overview - Anatomy & Physiology|left kidney]].
 
  
 
====Descending Colon====   
 
====Descending Colon====   
  
The descending colon is between 2-4m long. It is suspended by a long mesentery; ''mesocolon descendens''. The descending colon has '''two''' taenia. Between the two taenia are distinct sacculations that house the faecal balls.
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The descending colon is between 2-4 meters long. It is suspended by a long mesentery; ''mesocolon descendens''. The descending colon has '''two''' taeniae. Between the two taeniae are distinct sacculations that house the faecal balls.
  
 
===[[Rectal Examination of the Horse|Rectal Palpation]]===
 
===[[Rectal Examination of the Horse|Rectal Palpation]]===
  
[[Rectal Examination of the Horse|Rectal palpation]] is a useful technique and is often used to assess colic. Structures that can be palpated ''per rectum'' include; faecal balls in the descending colon, the [[Urinary Bladder - Anatomy & Physiology|bladder]], the [[Reproductive System Overview - Anatomy & Physiology|reproductive organs]] in the mare, the base of the [[Caecum - Anatomy & Physiology|caecum]], the root of the mesentery, the [[Urinary System Overview - Anatomy & Physiology|left kidney]], +/- the nephrosplenic ligament, the left dorsal colon and the pelvic flexure of the ascending colon. ''NB: This is a common site of impaction.''
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[[Rectal Examination of the Horse|Rectal palpation]] is a useful technique and is often used to assess [[:Category:Colic in Horses|colic]]. Structures that can be palpated ''per rectum'' include; faecal balls in the descending colon, the [[Urinary Bladder - Anatomy & Physiology|bladder]], the [[Reproductive System Overview - Anatomy & Physiology|reproductive organs]] in the mare, the base of the [[Caecum - Anatomy & Physiology|caecum]], the root of the mesentery, the [[Urinary System Overview - Anatomy & Physiology|left kidney]], +/- the nephrosplenic ligament, the left dorsal colon and the pelvic flexure of the ascending colon. ''NB: This is a common site of impaction.''
  
 
===Microbial Environment===
 
===Microbial Environment===
  
Microbes convert carbohydrates to [[Volatile Fatty Acids|volatile fatty acids]] (VFAs). The horse receives 75% of it's energy requirements from VFAs. The large intestine is buffered by the secretion of large amounts of bicarbonate from the [[Pancreas - Anatomy & Physiology|pancreas]] and the [[Ileum - Anatomy & Physiology|ileum]]. Glands in the wall of the [[Large Intestine - Anatomy & Physiology|large intestine]] may also produce bicarbonate. The microbial population exists in the [[Caecum - Anatomy & Physiology|caecum]] and ventral colon.  
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Microbes convert carbohydrates to [[Volatile Fatty Acids|volatile fatty acids]] (VFAs). The horse receives 75% of its energy requirements from VFAs. The large intestine is buffered by the secretion of large amounts of bicarbonate from the [[Pancreas - Anatomy & Physiology|pancreas]] and the [[Ileum - Anatomy & Physiology|ileum]]. Glands in the wall of the [[Large Intestine - Anatomy & Physiology|large intestine]] may also produce bicarbonate. The microbial population exists in the [[Caecum - Anatomy & Physiology|caecum]] and ventral colon.  
  
It is mixed; there are both bacteria and protozoa. Microbes are anaerobic. The microbial population is dependent on diet and frequency of feeding, as different microbes are suited to digesting different things. The number of microbes can change 100 fold in a 24 hour period. [[Volatile Fatty Acids|VFAs]] produced are absorbed across the intestinal wall. Urea from the blood is transported to the intestinal lumen to be used by microbes, which also use nitrogen from the diet. Environmental factors of the [[Caecum - Anatomy & Physiology|caecum]] and ventral colon can influence fermentation of microbial population.
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The environment is mixed; there are both bacteria and protozoa. Microbes are anaerobic. The microbial population is dependent on diet and frequency of feeding, as different microbes are suited to digesting different particles. The number of microbes can change 100 fold in a 24 hour period. [[Volatile Fatty Acids|VFAs]] produced are absorbed across the intestinal wall. Urea from the blood is transported to the intestinal lumen to be used by microbes, which also use nitrogen from the diet. Environmental factors of the [[Caecum - Anatomy & Physiology|caecum]] and ventral colon can influence fermentation of microbial population.
  
Environmental factors include: Frequent intake of food, constant temperature, constant mixing, removal of the products of fermentation by absorption and peristalsis and the stable osmotic environment i.e. normal intake of water.
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Environmental factors include: frequent intake of food, constant temperature, constant mixing, removal of the products of fermentation by absorption and peristalsis and the stable osmotic environment i.e. normal intake of water.
  
 
[[Volatile Fatty Acids|VFA's]] produced include Acetate, Propionate and Butyrate. Factors that promote VFA production include an optimum pH of 6.5, an anaerobic environment and gut motility.
 
[[Volatile Fatty Acids|VFA's]] produced include Acetate, Propionate and Butyrate. Factors that promote VFA production include an optimum pH of 6.5, an anaerobic environment and gut motility.
  
==Liver==
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==[[Liver - Anatomy & Physiology|Liver]]==
The liver is contained entirely within the rib cage, to the right of the midline. It is less lobated. There is no [[Gall Bladder - Anatomy & Physiology|gall bladder]] and the left lobe is subdivided. There is no papillary lobe. In the foal, the liver is larger and more symmetrical. The bile duct opens into the [[Duodenum - Anatomy & Physiology|duodenum]] at the same papillae as the major pancreatic duct. Bile is constantly secreted.
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The liver is contained entirely within the rib cage, to the right of the midline. It is less lobated than in other species. The larger right lobe is undivided, and the left lobe subdivided. The caudate lobe is notched at the ventral free border. There is no papillary process. Horses have no [[Gall Bladder - Anatomy & Physiology|gall bladder]], and the hepatic ducts are relatively wide as a result. In the foal, the liver is larger and more symmetrical. The bile duct opens into the [[Duodenum - Anatomy & Physiology|duodenum]] at the same papillae as the major pancreatic duct. Bile is constantly secreted.
  
==Pancreas==
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==[[Pancreas - Anatomy & Physiology|Pancreas]]==
 
The pancreas lies mainly on the right, in the very dorsal part of the abdomen. It is triangular in shape and lies within the sigmoid flexure of the [[Duodenum - Anatomy & Physiology|duodenum]]. The lobes are less distinguishable compared to the dog. The ventral surface is directly attached to the right dorsal [[Colon - Anatomy & Physiology|colon]] and base of the [[Caecum - Anatomy & Physiology|caecum]]. The dorsal surface is directly attached to the right kidney and [[Liver - Anatomy & Physiology|liver]]. The portal vein perforates the pancreas at the '''pancreatic ring'''. Both the pancreatic and accessory ducts persist throughout development. There is a constant secretion of pancreatic juice, which increases after feeding. This provides the caecum and colon with a constant supply of buffered solution, which maintains a stable environment important for microbe survival.
 
The pancreas lies mainly on the right, in the very dorsal part of the abdomen. It is triangular in shape and lies within the sigmoid flexure of the [[Duodenum - Anatomy & Physiology|duodenum]]. The lobes are less distinguishable compared to the dog. The ventral surface is directly attached to the right dorsal [[Colon - Anatomy & Physiology|colon]] and base of the [[Caecum - Anatomy & Physiology|caecum]]. The dorsal surface is directly attached to the right kidney and [[Liver - Anatomy & Physiology|liver]]. The portal vein perforates the pancreas at the '''pancreatic ring'''. Both the pancreatic and accessory ducts persist throughout development. There is a constant secretion of pancreatic juice, which increases after feeding. This provides the caecum and colon with a constant supply of buffered solution, which maintains a stable environment important for microbe survival.
  
 
{{Template:Learning
 
{{Template:Learning
 
|flashcards = [[Hindgut Fermenters - Horse - Anatomy & Physiology - Flashcards|Horse digestive system]]
 
|flashcards = [[Hindgut Fermenters - Horse - Anatomy & Physiology - Flashcards|Horse digestive system]]
|videos = [[Video: Foal gastrointestinal tract potcast|Foal gastrointestinal tract potcast]]<br>[[Video: Abdominal viscera of the horse dissection|Abdominal viscera of the horse dissection]]<br>[[Video: Equine left-sided abdominal and thoracic topography dissection|Equine left-sided abdominal and thoracic topography dissection]]<br>[[Video: Equine left-sided abdominal and thoracic topography dissection 2|Equine left-sided abdominal and thoracic topography dissection 2]]<br>[[Video: Equine stomach potcast|Equine stomach potcast]]
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|videos = [[Video: Foal gastrointestinal tract potcast|Foal gastrointestinal tract potcast]]<br>[[Video: Abdominal viscera of the horse dissection|Abdominal viscera of the horse dissection]]<br>[[Video: Equine left-sided abdominal and thoracic topography dissection|Equine left-sided abdominal and thoracic topography dissection]]<br>[[Video: Equine left-sided abdominal and thoracic topography dissection 2|Equine left-sided abdominal and thoracic topography dissection 2]]<br>[[Video: Equine stomach potcast|Equine stomach potcast]]<br><br>
 +
|OVAM = [http://www.onlineveterinaryanatomy.net/content/equine-head-and-dentition-powerpoint PowerPoint covering the anatomy and physiology of the equine head and dentition, including the skeletal aspects, the physiology of mastication and it’s associated anatomy as well as common dental abnormalities.]<br>[http://www.onlineveterinaryanatomy.net/content/horse-caecum-and-colon-left-view Equine Caecum and Colon - Left View]<br>[http://www.onlineveterinaryanatomy.net/content/horse-caecum-and-colon-right-view Equine Caecum and Colon - Right View]<br>[http://www.onlineveterinaryanatomy.net/content/equine-oesophagus-histology Equine Oesophagus Histology]<br>[http://www.onlineveterinaryanatomy.net/content/equine-duodenum-histology Equine Duodenum Histology 1]<br>[http://www.onlineveterinaryanatomy.net/content/equine-duodenum-histology-0 Equine Duodenum Histology 2]<br>[http://www.onlineveterinaryanatomy.net/content/smooth-muscle-histology-equine-duodenum-0 Smooth Muscle Histology of Equine Duodenum]
 
}}
 
}}
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 +
==Webinars==
 +
<rss max="10" highlight="none">https://www.thewebinarvet.com/gastroenterology-and-nutrition/webinars/feed</rss>
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[[Category:Horse Anatomy]]

Latest revision as of 19:42, 27 October 2022


Introduction

The horse is a monogastric hindgut fermenter. The horse evolved for grazing and it does so for up to 17 hours a day. A high proportion of the horse's dietary carbohydrate is in the form of starch. A mature horse eats 2-2.5% of it's body weight in dry matter every day, 1.5-1.75% of this should be fibre (hay/haylage). This is to prevent a rapid drop in pH in the large intestine and also to stimulate peristalsis in the gut and prevent build up of gas.

Oral Cavity

Teeth

Tooth identifation in the horse - © Academy of Equine Dentistry-2008
Horse tooth - © Malcom Morley

Dental Formula

The formula for deciduous teeth: 2 (I3/3 C0/0 P3/3)
The formula for permanent teeth: 2 (I3/3 C1/1 P3-4/3 M3/3)

Canines

The canines are rudimentary and are located in the diastema. The size of the root is proportionally larger than the crown.

Molars

The molars have enlarged surfaces and higher crowns. They have delayed root development and complicated folding of enamel.

Incisors

Incisors have high crowns and folded enamel surfaces. Their roots converge.

Premolars

A horse's Wolf tooth (PM1) is often lacking. Molars and Premolars form a continuous surface. The cheek teeth have a high rate of wear and continually erupt. The upper teeth are wider than the lower. There is no infundibulum in the lower teeth.

Ageing

Horses can be aged by their teeth. At two and a half years of age the first permanent incisor will erupt; at three and a half the second permanent incisor will erupt and at four and a half the third permanent incisor will erupt. Over five years of age the folding of the enamel ring (infundibulum) can indicate age. There is a seven year hook and over 13 years of age a dental star will be present.

The Galvayne's Groove is a brown groove on the upper corner incisor teeth and indicates that the horse is over 10 years old. At 15 the groove will be approximately half way down the tooth; At 20 the groove will run down the whole tooth; Over 20 the groove begins to disappear; At 25 the groove will only be visible on the bottom half of the tooth. At 30 the groove will usually be gone.

Palate

Horses have a tight laryngeal cuff around the laryngeal entrance, therefore the soft palate cannot be raised for long periods of time. This causes them to be obligate nasal breathers. Laryngeal cuffing also prevents vomiting. There are no specific species diferences in the hard palate.

Oesophagus

In the horse, the oesophageal lumen narrows at the thoracic inlet and oesophageal hiatus of the diaphragm; this predisposes them to impaction (choke). Another factor specific to horses is that striated muscle exists only in the rostral 65% of the oesophagus.

Stomach

Equine Stomach with Margo Plicatus - © RVC 2008

The horse has a monogastric stomach located on the left side of the abdomen. A region called the margo plicatus is present which separates the glandular and non-glandular parts of the equine stomach. The non-glandular area is lined with squamous epithelium (not columnar).

The stomach is relatively small (10% GIT) and its capacity is 8-16 litres. The equine stomach is rarely empty, retention time is short and expulsion into the duodenum stops when feeding stops. Although fluid exits quickly, feed particles can be retained for more than 48 hours as digestion is initiated in the stomach. A 500kg horse can produce 30 litres of gastric juice in 24 hours. The strong cardiac sphincter allows movement of gas and fluid into the stomach, but not out of it. This prevents the animal from vomiting. Therefore, any disorder that results in aboral fluid movement from the small intestine results in fluid accumulation in the stomach (gastric reflux), dilation and eventually gastric rupture if left untreated.

Small Intestine

Duodenum

Section of equine duodenum- © RVC 2008

The descending duodenum is dorsal on the right side of the abdomen, suspended from the dorsal body wall by the mesoduodenum. The mesoduodenum is relatively short, so the duodenum is closely tethered in a constant position. In the right paralumbar fossa region, the descending duodenum turns towards the midline and is attached to the base of the caecum. The descending duodenum then runs caudally beneath the liver to the caudal pole of the right kidney where it has its caudal flexure to become the ascending duodenum.

Jejunum

The jejunum is confined to the left dorsal part of the abdomen associated with a long mesentery. It is restricted to this position by the large caecum on the right, and ascending colon ventrally on both sides.

Ileum

The terminal portion of the small intestine is the ileum, which joins the caecum at its dorso-medial aspect. The ileal mesentery attaches to the caecum at the dorsal caecal band.

Large Intestine

Undigested material spends a long time in the caecum and large intestine undergoing microbial fermentation, mainly of cellulose (95% after 65 hours).

In the hindgut of the horse; 75-85% of insoluble carbohydrates is digested, 15-30% of soluble carbohydrates and 30% of protein is digested. A lot of absorption of volatile fatty acids (VFAs) and water occurs in the large intestine which pass readily into the blood. Electrolytes are also absorbed in the large intestine; 95% of sodium and chloride and 75% of potassium and phosphate. To mix the contents of the large intestines, the taenia and circular muscle of the tunica muscularis contract. This also transports the ingesta through the large intestine and brings the products of fermentation in contact with the epithelium.

Caecum

The caecum is the main site of microbial fermentation, followed by the ascending then descending colons. It is located on the right side of the abdomen. It is very large, roughly 1m in length with a 30L capacity. It consists of a base, body and apex (blind ending). The base lies in the right dorsal part of the abdomen, in contact with the abdominal roof. The apex lies on the ventral abdominal wall, and terminates at the level of the xiphoid cartilage. It exists at the junction with the ileum and colon.

The caecocolic orifice is where the caecum opens into the ascending colon. This exists as a transverse slit formed by a constriction of the ascending colon. There is a sphincter at this point which prevents backward flow of ingesta when the colon contracts.

The ileum opens into the caecum at the ileal papilla. This is a small projection into the caecum housing the ileal sphincter and venous plexus that, together, control the ileal orifice.

Taeniae are present. Taeniae are formed by concentration of the longitudinal muscle layer. Between the taeniae are sacculations, or haustra. Haustra appear as folds on the interior surface. There are four taeniae over the caecum; dorsal, ventral, lateral and medial. The dorsal taenia provides the attachment site for the ileocaecal fold, which joins the caecum to the ileum.

The lateral taenia provides the attachment site for the caecocolic fold, which joins the caecum to the ascending colon. The ventral taenia is free.

The medial and lateral taeniae are where the caecal vessels and lymph nodes are located. Ingesta is regularly transported from the ileum to the caecum, this movement can be heard upon auscultation of the right dorsal quadrant of the caudal abdomen. Ausculatation of this area is carried out in the assessment of colic. In the horse, the caecum is responsible for the digestion of complex carbohydrates such as cellulose.

Colon

Ascending Colon

The ascending colon is very large and takes up most of the ventral abdomen. It is the shape of a double "U", where one "U" is on top of the other. There are four limbs that lie parallel to each other, and three flexures that change these direction of the limbs.

The sequence of the limbs and flexures of the ascending colon is as follows; Right Ventral Colon (for those with an RVC bias remember, "the RVC comes first!"), passes out of the caecocolic orifice on the right side of the abdomen and continues cranially to the xiphoid region; Sternal Flexure, passes across the midline from right to left, Left Ventral Colon, runs caudally on the left ventral abdominal floor; Pelvic Flexure, turns dorsally just cranial to the pelvic inlet and then runs cranially to the diaphragm, Left Dorsal Colon, runs cranially, parallel and dorsal to the left ventral colon; Diaphragmatic Flexure, turns caudally at the diaphragm; Right Dorsal Colon, continues caudally on the right. It is the shortest limb of the ascending colon.

The transverse colon continues on from the right dorsal colon as the right dorsal colon turns medially. The right dorsal colon is attached by a mesentery to the dorsal abdominal wall, the base of the caecum, the root of the mesentery and the pancreas. This anatomical arrangement of mesentery allows the left ascending colon to twist and is a common cause of colic (colonic torsion).

The ventral parts of the ascending colon are attached to the dorsal parts by a short mesocolon. The mesocolon houses the blood vessels, nerves and lymphatics. In the ventral colon many important digestive and absorptive functions take place, whilst the dorsal colon is mainly responsible for transportation of ingesta. Taeniae are present. Different parts of the colon can be distinguished by the number of taeniae present:

The right and left ventral colon and the sternal flexure have four taeniae. The left dorsal colon and pelvic flexure have one taenia and the right dorsal colon and diaphragmatic flexure have three taeniae.

Transverse Colon

The transverse colon is short. It passes from across the midline from right to left. It passes cranial to the root of the mesentery. It has two taeniae. It turns caudally to become the descending colon at the level of the left kidney.

Descending Colon

The descending colon is between 2-4 meters long. It is suspended by a long mesentery; mesocolon descendens. The descending colon has two taeniae. Between the two taeniae are distinct sacculations that house the faecal balls.

Rectal Palpation

Rectal palpation is a useful technique and is often used to assess colic. Structures that can be palpated per rectum include; faecal balls in the descending colon, the bladder, the reproductive organs in the mare, the base of the caecum, the root of the mesentery, the left kidney, +/- the nephrosplenic ligament, the left dorsal colon and the pelvic flexure of the ascending colon. NB: This is a common site of impaction.

Microbial Environment

Microbes convert carbohydrates to volatile fatty acids (VFAs). The horse receives 75% of its energy requirements from VFAs. The large intestine is buffered by the secretion of large amounts of bicarbonate from the pancreas and the ileum. Glands in the wall of the large intestine may also produce bicarbonate. The microbial population exists in the caecum and ventral colon.

The environment is mixed; there are both bacteria and protozoa. Microbes are anaerobic. The microbial population is dependent on diet and frequency of feeding, as different microbes are suited to digesting different particles. The number of microbes can change 100 fold in a 24 hour period. VFAs produced are absorbed across the intestinal wall. Urea from the blood is transported to the intestinal lumen to be used by microbes, which also use nitrogen from the diet. Environmental factors of the caecum and ventral colon can influence fermentation of microbial population.

Environmental factors include: frequent intake of food, constant temperature, constant mixing, removal of the products of fermentation by absorption and peristalsis and the stable osmotic environment i.e. normal intake of water.

VFA's produced include Acetate, Propionate and Butyrate. Factors that promote VFA production include an optimum pH of 6.5, an anaerobic environment and gut motility.

Liver

The liver is contained entirely within the rib cage, to the right of the midline. It is less lobated than in other species. The larger right lobe is undivided, and the left lobe subdivided. The caudate lobe is notched at the ventral free border. There is no papillary process. Horses have no gall bladder, and the hepatic ducts are relatively wide as a result. In the foal, the liver is larger and more symmetrical. The bile duct opens into the duodenum at the same papillae as the major pancreatic duct. Bile is constantly secreted.

Pancreas

The pancreas lies mainly on the right, in the very dorsal part of the abdomen. It is triangular in shape and lies within the sigmoid flexure of the duodenum. The lobes are less distinguishable compared to the dog. The ventral surface is directly attached to the right dorsal colon and base of the caecum. The dorsal surface is directly attached to the right kidney and liver. The portal vein perforates the pancreas at the pancreatic ring. Both the pancreatic and accessory ducts persist throughout development. There is a constant secretion of pancreatic juice, which increases after feeding. This provides the caecum and colon with a constant supply of buffered solution, which maintains a stable environment important for microbe survival.


Alimentary System - Horse Anatomy Learning Resources
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Flashcards
Test your knowledge using flashcard type questions
Horse digestive system
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Videos
Selection of relevant videos
Foal gastrointestinal tract potcast
Abdominal viscera of the horse dissection
Equine left-sided abdominal and thoracic topography dissection
Equine left-sided abdominal and thoracic topography dissection 2
Equine stomach potcast

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OVAM
Anatomy Museum Resources
PowerPoint covering the anatomy and physiology of the equine head and dentition, including the skeletal aspects, the physiology of mastication and it’s associated anatomy as well as common dental abnormalities.
Equine Caecum and Colon - Left View
Equine Caecum and Colon - Right View
Equine Oesophagus Histology
Equine Duodenum Histology 1
Equine Duodenum Histology 2
Smooth Muscle Histology of Equine Duodenum


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