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Comparative Digestive Physiology

Comparative Digestive Physiology. Why Do Animals Digest?. Food not ingested in suitable state Physical nature of food determined by: gathering apparatus for uptake type of digestive system . Primary Functions of the Digestive Tract. Transport food – peristaltic contractions

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Comparative Digestive Physiology

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  1. Comparative Digestive Physiology

  2. Why Do Animals Digest? Food not ingested in suitable state Physical nature of food determined by: gathering apparatus for uptake type of digestive system

  3. Primary Functions of the Digestive Tract • Transport food – peristaltic contractions • Digestion • Mechanical breakdown • Chemical breakdown • Absorption • Passive diffusion and active transport • Synthesis - true protein, FA, starch, vitamins • Excretion – elimination of waste products • Via bile (toxins, microbes etc) • Via rectum (Ca, Mg, P)

  4. Regions of Alimentary Canal • Foregut functions • Ingestion and storage of feeds • Midgut functions • Mechanical, chemical & enzymatic digestion of feed • Nutrient absorption • Hindgut functions • Water & ion re-absorption • Formation, storage, excretion of feces

  5. Associated Structures • Pancreas • Liver • Gallbladder • Salivary glands Contribute to small intestinal digestion

  6. Primitive Gastrointestinal Tract • Found in monotremes (egg-laying mammals), insectivores (bats, shrews, moles), and dermopterans (colugos) • Simple stomach, little or no division between small intestines and large intestines, large intestine simple, presence of cecum, non-sacculated colon

  7. Species-Dependent Nutritional Adaptations • Includes involvement of: • Teeth • Jaws and jaw musculature • Alimentary canal • Stomach - May be simple or become sacculated to compartmentalize functions for prolonged storage of feed and utilization of bacterial fermentation (langurs and ruminants) • May also become voluminous for storage of large amounts of feed (vampire bats) • Large intestine - varies substantially in length, compartmentalization, and complexity among species

  8. Ruminants • 2.8 billion domesticated ruminants • Cattle, sheep, deer, elk, bison • Pregastric fermentation • Ability to chew cud at frequent intervals distinguishes true ruminant from other foregut fermenters • Kangaroo, colobine monkey are not true ruminants • Four compartment stomach • Reticulum • Rumen • Omasum • Abomasum

  9. Ruminants vary in size and habitat

  10. Classification of Ruminants by Feeding Preference • Classes of ruminants • Concentrate selectors • Intermediate feeders • Roughage grazers

  11. Concentrate Selecting Species • Properties • Evolved early • Small rumens • Poorly developed omasums • Large livers • Limited ability to digest fiber • Classes • Fruit and forage selectors • Very selective feeders • Duikers, sunis • Tree and shrub browsers • Eat highly lignified plant tissues to extract cell solubles • Deer, giraffes, kudus

  12. Intermediate Feeding Species • Properties • Seasonally adaptive • Feeding preference • Prefer browsing • Moose, goats, elands • Prefer grazing • Sheep, impalas

  13. Roughage Grazing Species • Properties • Most recently evolved • Larger rumens and longer retention times • Less selective • Digests fermentable cell wall carbohydrates • Classes • Fresh grass grazers • Buffalo, cattle, gnus • Roughage grazers • Hartebeests, topis • Dry region grazers • Camels, antelope, oryxes

  14. Structures in Mouth • Lips • Teeth • Tongue • Salivary glands

  15. Mouth • Functions • Grasp food • Taste • Masticate food • Mix with saliva

  16. Digestion in the Mouth • Prehension • Bringing the food to the mouth • Upper limbs, head, beak, claws, mouth, teeth and lips • Mastication or chewing • To crush the food, increase surface area and allow enzymes to act on molecules • Carnivores only to reduce the size of the particle to a size small enough to swallow • Herbivores must chew continuously (40-50,000 times a day) to increase surface area

  17. Prehension • Seizing and conveying feed to mouth • Mechanisms vary with behavior and diet • Forelimbs • Primates, raccoon • Snout • Elephant, tapir • Tongue • Anteater, cow, sheep • Lips • Horse, sheep, rhinoceros

  18. Prehension • Domestic mammals use lips, teeth and tongue • Relative importance varies by species • Horses • lips when eating from manger • teeth when grazing • Cows and sheep have limited use of lips • Use long rough tongue to grasp forage • Pigs use snout to root in ground and pointed lower lip to convey feed into mouth • Birds use beak and tongue • Drinking varies as well • Most mammals use suction • Dogs and cats use tongue to form ladle

  19. White Rhino (“wijd” = wide) Squared off upper lip used to “crop” grass Grazes on savannah Black Rhino Prehensile upper lip for browsing Consumes bushes and shrubs in forest The Importance of Prehension in Diet Formulation

  20. Mastication • Physical reduction of feed • Especially important in non-ruminant herbivores • Adaptations with teeth • Carnivores • Herbivores • Edentates (sloths, armadilloes, anteater) • Relative toothlessness

  21. Morphological Adaptations for Herbivory • All related to finding, ingesting, masticating, and digesting plant cell walls • Dental adaptations for herbivory include changes to incisors, molar occlusal surfaces, & masseter • Solution for digestive problems is to provide a place in digestive tract for anaerobic bacteria & protozoans (microflora) to colonize

  22. Monogastric Teeth • Function: • Mechanically reduce particle size • Increase surface area Four types: • Incisors are used for cutting • Canine (fangs, eye teeth, tusks) are tearing teeth • Premolars and molars (cheek teeth) grind the food

  23. Ruminant Mouth - Teeth Function: • Reduce particle size Anatomy: • Upper dental pad • Lower incisors • Premolars • Molars

  24. Teeth Specializations • Carnivores • Canine teeth highly developed and used for tearing • Molars are pointed for bone crushing

  25. Teeth Specializations • Omnivores • Grinding teeth patterns on posterior teeth (molars) • Piercing and ripping cusps on anterior teeth (incisors) • Tongue - used to move feed to teeth

  26. Jaw & Teeth Specializations • Non-ruminant herbivores (horse) • Incisors for nipping, molars slightly angled, jaws move circularly (vertical and lateral) • Ruminants • No upper incisors, have dental pad, molars allow only lateral movements • Different classes - roughage eaters, transition types, selective eaters all differ in tongue mobility and cleft palate

  27. Ruminant Mouth • Lips range from short, relatively immobile in nonselective grazing species to very mobile (prehensile) in selective grazing or concentrate selecting species • Chew in a lateral (grinding) motion on one side of mouth at a time • Needed to increase surface area of feed particles • Feed chewed primarily during rumination in grazing species

  28. Jaw Muscles and Mastication • Temporalis muscle - develops maximum force on anterior portion of jaw (largest muscle in carnivores and smallest muscle in herbivores) • Masseter and medial pterogoid - maximum force for crushing and grinding • Lateral pterogoid - allows lateral movement which is important for grinding (highly important in herbivores, but carnivores and many omnivores have almost no lateral movement of jaws)

  29. Monogastric Tongue Function: • Comprised of three muscles • Maneuvers food in the mouth • Moves feed to teeth for grinding and to the back of the mouth for swallowing • Can distinguish between feed and toxins by papillae or taste buds

  30. Ruminant Mouth - Tongue • Drinking, chewing and forming boluses • Prehension of feed • Covered with rough, hook-like papillae that assist in grasping feed • Important in nonselective grazing species • Taste buds • More numerous than monogastric species • More numerous on nonselective grazing species • Believed that taste is primarily used for food avoidance by grazing species while concentrate selecting species select on the basis of smell

  31. Monogastric Salivary Glands Types of Glands: Zygomatic Parotid Sublingual Mandibular

  32. Functions of Saliva • Moisten feed (salt and water) • Lubrication (aids swallowing) • Starch and(or) lipid digestion (amylase and(or) lipase)

  33. Salivary Glands

  34. Monogastric Salivary Glands • Flow rate affected by: • Parasympathetic nervous system • Increased tone = Increased flow • Increased flow = Increased dilution • Sympathetic nervous system • Increased tone = Decreased flow • Decreased flow = Increased concentration

  35. Ruminant Mouth - Saliva • From at least three paired glands • Submaxillary, sublingual, parotid (50% of secretions) • Aids in mastication, swallowing, forming bolus • No digestive enzymes in the saliva of mature ruminants • Provides N, P, S and Na for rumen microoganisms • Buffering compounds to maintain rumen pH and mucin to prevent bloat

  36. Salivation • Quantity and composition of saliva varies considerably between species • Quantity related to level of chewing activity • Amount of secretion • Dogs minimal (lubrication, no enzymes) • Sheep 3-10 liters/d • Horse 10-12 liters/d • Cattle 130-180 liters/d

  37. Deglutition (Swallowing) • Reflex initiated by presence of food in pharnyx • Propulsion of food to stomach by esophageal peristalsis

  38. Monogastric Esophagus • Horse/Pig: • Striated muscles for first 2/3 • Smooth muscles for last 1/3 • In horse, esophagus joins stomach at an oblique angle and cardiac sphincter (the valve between the stomach and esophagus) only allows one-way flow • MOST horses cannot belch out gas or vomit • Dog: • Striated muscles throughout allow GREAT control of digesta movement both directions

  39. Ruminant Esophagus • Involved in rumination • Different from monogastric esophagus • Striated muscle along the entire length • Provides greater strength • Allows some voluntary control • Funnel shaped • Contains three sphincters active in rumination and eructation

  40. Esophagus • Species adaptations • Ability to control peristaltic contractions • Reverse peristalsis • Amount and location of skeletal muscle • Regurgitation vs. vomiting

  41. Foregut in Birds • Crop • Bottom of the esophagus forms a sac called crop • Stores undigested food. • Birds with crop gorge when food is available, store it in crop, and slowly digest it later

  42. Stomach • Monogastric • One compartment • Varies in size by species • Ruminant • Four compartments • Reticulum • Rumen • Omasum • Abomasum

  43. Gastric Digestion • Functions • Reservoir for controlled release of digesta to small intestine • Horse has small capacity – requires increased number of smaller sized meals • Mixing food • Mechanical breakdown of feed • Hydrolytic digestion by acid and enzymes • Mainly protein • Kill bacteria • Secrete intrinsic factor: needed for vitamin B12 absorption • Hormone production

  44. Stomach Regions • Esophageal • Non-glandular • Cardiac • Secretes mucus • Fundic • Parietal cells • Chief cells • Pyloric • Mucus

  45. Gastric Pits • Formed by numerous folds in the epithelium • Glands empty into the gastric pit • Many types of glands may empty into one gastric pit

  46. Gastric Glands

  47. HCl Decreases pH (~2-3) Denatures protein Kills bacteria Activates pepsinogen Mucus Protects lining from acid and enzymes No “autodigestion” Lubricant Pepsinogen Activated form is pepsin Hydrolyzes protein Rennin (abomasum) Clots milk Lipase Some species Stomach Secretions

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