1 / 26

Motivation and the Regulation of Internal States Hunger: A Complex Drive

Motivation and the Regulation of Internal States Hunger: A Complex Drive. Hunger: learning factors. Much of what we eat is culturally driven or learned Basic food preferences (5 tastes) Some physiological need But mostly learning! Learned taste aversion:

Lucy
Download Presentation

Motivation and the Regulation of Internal States Hunger: A Complex Drive

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Motivation and the Regulation of Internal States Hunger: A Complex Drive

  2. Hunger: learning factors • Much of what we eat is culturally driven or learned • Basic food preferences (5 tastes) • Some physiological need • But mostly learning! • Learned taste aversion: • the avoidance of foods associated with illness or poor nutrition • Often occurs in one trial. • Learned taste preference • Preference for the flavor of a food • Probably developed to remember taste of food that contains a needed nutrient. • Often we choose a food based on taste, not nutrient contents!

  3. communicating about food depends on the kind of animal we are! • What is a poison or bad food? • How do humans figure out a food is rotten or poison? • How do other animals judge “bad food”- what clues do they use? • Why might we learn after only 1 experience that a food is bad- why don’t we keep eating food that made us sick?

  4. Garcia Effect or Conditioned Taste Aversion • Grp I: Tasty Water--> Nausea • Good Conditioning • Grp II: Bright Noisy Water-> Shock • Good conditioning • Grp III: Tasty Water--> Shock • No conditioning • Grp IV: Bright Noisy water--> Nausea • No conditioning

  5. A “biological boundary” • Look at the TYPE of stimuli that are being used: • Categorize each as an internal or external event • Grp I: Tasty Water--> Nausea • InternalInternal • Grp II: Bright Noisy Water-> Shock • ExternalExternal • Grp III: Tasty Water--> Shock • InternalExternal • Grp IV: Bright Noisy water--> Nausea • External Internal • Can’t learn ACROSS modalities very well!

  6. Important Properties • Just takes once! • All animal species show it • Can remember the poison for a VERY long time! • Novel stimuli condition more readily than familiar stimuli • Different Cues for different species: • quail: color of food • monkeys: texture • rats: taste and smell • In social animals- can transmit stimulus socially

  7. Uses • Humans: dietary restrictions and smoking cessation programs (but will switch brands and tastes) • Can develop CTA with Chemotherapy- must watch pairing good food with nausea • Most important use: Wildlife Management: • Coyote management • Wolf management • Bear management

  8. keep your dog out of the garbage?

  9. Starting and stopping eating • What starts and stops eating? Complex factors • Local theories: Cannon & Washburn • Hunger = sensation arising from gastrointestinal tract • Tied to some “sign”: • Increase in gastric juices • Full stomach • Balloon experiment: swallow balloon and fill/empty it • Subjects with filled balloon ate less, reported feeling more full • But, still ate! • Central theories: homeostatic physiological processes • Starting process • Stopping process • Selection process: what to eat and when!

  10. Process of digestion • Digestion begins in the mouth, where food is ground fine and mixed with saliva. • Saliva: • provides lubrication • contains an enzyme that starts the breakdown of food. • Digestion proceeds in the stomach: • food is mixed with the gastric juices hydrochloric acid and pepsin. • Broken down more before enters intestines • Small intestine • Receives partially processed food from stomach • Stomach releases food gradually so the small intestine has time to do its job.

  11. digestion • Duodenum • Initial 25 cm of small intestine • Digesting primarily occurs here • Carbohydrates are metabolized into simple sugars, particularly glucose. • Proteins are converted to amino acids. • Fats are transformed into fatty acids and glycerol. • Area postrema: • Area of brain outside the blood-brain barrier • Most posterior portion of brain • Exempt from blood-brain barrier functions, so toxins can activate it to induce vomiting.

  12. Phases of digestion • Absorptive phase • Thefew hours following a meal • body lives off the nutrients arriving from the digestive system; • Insulin release: • hormone that enables body cells to take up glucose for energy and certain cells to store excess nutrients. • The pancreas secretes during absorption phase • Storage: Some of the glucose is converted to glycogen and stored in a short-term reservoir in the liver and muscles. • Fat reserves: Any remaining glucose is converted into fats and stored in fat cells, also known as adipose tissue.

  13. Digestion phases • Fasting Phase • Eventually the glucose level in the blood drops • body must falls back on its energy stores • This is the fasting phase. • The pancreas ceases secretion of insulin • starts secreting the hormone glucagon, • glucagon causes the liver to transform stored glycogen back into glucose. • When levels are low enough, starts signals for eating again. • but; social and environmental cues can also trigger “hunger”

  14. Initiation of hunger • Three major physiological changes with hunger: • Glucopruvic hunger: low glucose signaled to brain • Lipoprivic hunger: low fatty acids • Ghrelin: neuropeptide in stomach • Liver monitors • glucose level • fatty acids in blood passing from liver to small intestine • Monitors fatty acids via hepatic portal vein • Vagus nerve carries signals from liver to NST in medulla • NST sends signals to arcuate nucleus of hypothalamus • vital hypothalamic structure • monitors the body’s nutrient condition. • This is like the thermostat in temperature regulation

  15. Initiation of hunger • Thearcuate nucleus sends signals to the PVN (paraventricular nucleus) • Also part of hypothalamus- ventral medial part • initiates eating, though less effectively than the lateral hypothalamus, • regulates metabolic processes such as body temperature, fat storage, and cellular metabolism. • Modulates control via two nerotransmitters: • Neuropeptide Y (NPY); serotonin • Lateral hypothalamus: master control of eating • initiates eating • controls several aspects of feeding behavior as well as metabolic responses.

  16. Critical initiation hormones • NPY (neuropeptide Y) • released from the PVN and lateral hypothalamus • Released in response to signals from the arcuate nucleus • dramatically increases eating • But reduces metabolism. • Gherkin • Peptide that is synthesized in the stomach and released during fasting. • Also induces eating • Involved in eating disorders such as PraderWilli syndrome • 2.5 x higher in individuals with PraderWilli’s • Gherkin blocker may be an important dietary manipulation

  17. PraderWilli Syndrome • Genetic disorder: due to malfunction of cell division • caused by a gene missing on part of chromosome 15. • most patients missing genetic material on part of the father's chromosome; • others have two copies of the mother's chromosome 15. • the genetic changes occur randomly. Patients usually do not have a family history of the condition. • Symptoms • Newborns with this disorder small for gestational age; males have underdeveloped genitals • difficulties with sucking and swallowing; problems with weight gain • May seem floppy and feel like a "rag doll" when held; weak cry • Facial changes, such as "almond-shaped" eyes and a small, downturned mouth; Skin differences • Very small hands and feet compared to the body

  18. PraderWilli Syndrome • Affected children have intense craving for food; will do almost anything to get it. • results in uncontrollable weight gain and morbid obesity. • Morbid obesity may lead to lung failure • also low blood oxygen levels, right-sided heart failure, and death. • Signs and tests • Abnormal glucose tolerance • Above normal level of the hormone insulin in the blood • Failure to respond to luteinizing hormone releasing factor • High carbon dioxide levels; low oxygen • Obesity is the greatest threat to health.

  19. PraderWilli Syndrome

  20. Manipulating onset of eating • Stopping eating: Blocking NPY or gherkin or damage to LH or PVN greatly disrupts eating • Starting/maintaining eating: Injections of NPY into PVN results in huge increase in eating • Rats may gain 6x or more body weight • Can also induce by lesioning PVN • Really can’t stop eating! • During extreme deprivation: NPY reduces metabolism and increases motivation to eat • By decreasing metabolism, conserve body fat/glucose stores • At same time, make animal more active, thus more likely to get food • Also suppresses sexual behavior- • Again conserves energy • Also lessens chances of producing nonviable offspring

  21. Signaling an end to a meal • Mouth factors: • Full mouth • Chewing • Learning • Stomach factors • Full stomach is a cue to stop • Phillips and Powley (1996): • Inflated cuff to close off stomach/duodenum • Infused glucose into stomach • Infused saline into stomach • As long as stomach felt “full” – ate less • Also respond to caloric intake • High calorie soup produces greater reduction in eating than low-calorie soup • Issue of diet drinks: may eat MORE when drink diet drinks- not get satiety signal • Optimal factor: mouth+stomach+intestines signal to brain

  22. Signaling an end to a meal • Stomach and intestines respond to food by releasing various peptides that brain uses to monitor intake • Some peptides respond to carbohydrates • Some to fats • Some to proteins • Some to mixes • Peptides induce pancreas, liver, gallbladder to secrete appropriate enzymes indo duodenum • Allows appropriate digestion of specific nutrients • Signal to brain which nutrients digested via vagus nerve or bloodstream

  23. Satiety hormones • CCK (cholecystokinin) • The best known of the satiety signals • a peptide hormone that is released as food passes into the duodenum. • CCK detects fats and causes the gall bladder to inject bile into the duodenum, which breaks down the fat so it can be absorbed. • Relatively short term regulation • PYY (peptide YY3-36) • Another appetite-suppressing peptide hormone • released in the intestines in response to food • carried by the blood stream to the arcuate nucleus; inhibits the NPY-releasing neurons. • Note: non-neural route to the brain thus action is too slow to limit the current meal; • instead it decreases calorie intake by about a third over the following 12 hours. • LONG term regulation

  24. Satiety hormones • leptin. • Fat cells secrete leptin • inhibits eating • The amount of leptin in the blood proportional to body fat. • Leptin helps regulate meal size, • Regulates in response to long-term stores of fat rather than the nutrients contained in the meal. • Can demonstrate effect of these hormones: VMH lesions (much like PraderWilli’s syndrome) • Increase parasympathetic activity in vagus nerve • Enhances insulin release • Creates persistent absorption phase in which more nutrients are stored rather than used • Animal MUST overeat to maintain normal energy level • BUT: also becomes obese because of huge storage

More Related