1 / 22

Metabolism—How do we obtain energy from foods?

Metabolism—How do we obtain energy from foods?. Susan Algert, Ph.D., R.D. Metabolism. Human body releases energy from chemical bonds in nutrients the body uses for fuel. As bonds break they release energy During metabolism, energy, water and carbon dioxide are released.

salena
Télécharger la présentation

Metabolism—How do we obtain energy from foods?

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. Metabolism—How do we obtain energy from foods? Susan Algert, Ph.D., R.D.

  2. Metabolism • Human body releases energy from chemical bonds in nutrients the body uses for fuel. • As bonds break they release energy • During metabolism, energy, water and carbon dioxide are released

  3. Energy yielding nutrients • From carbohydrates—glucose • From lipids (trigylcerides)—glycerol and fatty acids • From proteins—amino acids

  4. The Cell • Cells are work centers of metabolism • Cells have similar structures • Two basic parts—nucleus and cytoplasm • Mitochondria are power generators that contain energy generating pathways

  5. Breaking down glucose for energy--aerobic • 6-C glucose split in half making two 3-Carbon compounds • Glycolysis means glucose splitting • -Carbon compounds become 2 pyruvates • Pyruvates will break down further to form ATP and heat

  6. Glucose retrieval via the Cori cycle--anaerobic • When less oxygen is available, pyruvate is converted to lactic acid • Liver can convert lactic acid to glucose in a recycling process • Pathway is muscle glycogen to glucose to pyruvate to lactic acid ( in liver) to glucose to glycogen

  7. Pyruvate to Acetyl Co-A • Irreversible step • Aerobic • Acetyl Co A to Carbon Dioxide via the TCA cycle Electron Transport Chain • Acetyl Co-A to fat

  8. Pyruvate is pivotal • ATP levels are low—metabolic pathways flow toward the production of ATP • Depending on O-2; ATP routes pyruvate to acetyl Co-A or lactate • ATP is abundant; pyruvate converted to oxaloacetate or amino acid alanine; oxaloacetate converted to glucose and then glycogen

  9. Acetyl Co-A at the crossroads • Breakdown pathways for glucose, fatty acids and some amino acids converge at acetyl-CoA. • Acetyl Co-A cannot return to pyruvate, but enters energy making pathways • Acetyl Co-A can also make ketone bodies and fatty acids

  10. Glycerol and fatty acids • Glycerol to pyruvate • Fatty acids to Acetyl Co-A Beta oxidation • Glucose not retrievable from fatty acids • Breakdown of acetyl-Co-A • Fat burns in flame of carbohydrate

  11. When a person draws on stores • Fat used to fuel brain • Acetyl Co-A fragments from fatty acids combine to produce ketone bodies • Ketone bodies can provide some fuel for brain cells • When ketone bodies contain an acid group they are called keto acids (COOH)

  12. Energy Compounds • ATP used to power cellular functions • NADH and FADH-2 carry energy for synthesis of ATP • NADPH delivers energy for biosynthesis

  13. Amino Acid Catabolism • Amino acids are deaminated and enter TCA cycle • Amino acids used to make pyruvate can make glucose • Amino acids that make Acetyl Co-A provide energy or body fat but not glucose

  14. Energy retrievable from amino acids- • Glucogenic amino acids- a.a. broken down into pyruvate or intermediate of the TCA cycle; gluconeogenesis • Ketogenic amino acids—an a.a.a broken down into acetyl CoA which can be converted into ketone bodies

  15. Transamination • Transfer of amino group from one amino acid to a keto acid, producing a new non essential amino acid and a keto acid

  16. Electron Transport Chain • Series of proteins that serve as electron carriers • Mounted in sequence on membrane inside mitochondria • Carriers receive electrons, it passes electrons and gives up energy until end when any usable energy has captured body’s ATP molecules

  17. TCA and ETC • Body’s most efficient means of capturing the energy from nutrients and transferring it into the bonds of ATP • Last step of ETC low energy electrons with H atoms combine with O2 from the lungs to make H2O

  18. Which fuels can make glucose • Parts of protein and fat that can make pyruvate can provide glucose; parts that make acetyl Co A cannot, but provide fat • Glucose is needed to fuel CNS and red blood cells • If there is not enough glucose the body will break down protein

  19. Making glucose on low Carb diets • Fat delivers mostly acetyl, so that you need to break down protein tissue to make glucose • High protein diets make your body convert protein to glucose and convert ammonia to urea in the liver • Urea is excreted via the kidneys • Water is needed to excrete urea

  20. Energy yielding nutrients-fat provides most kcals per gram • Nearly all bonds in a fatty acid are between carbons and hydrogens • Oxygen can be added to all of them (making CO2 and H2O) • Energy in bonds is released as they are oxidized • Glucose has less potential for oxidation as oxygen is already bonded to each C

  21. Feasting • Surplus protein—Deaminate and convert to acetyl Co-A and fat • Surplus carbohydrate--Glycogen • Surplus fat--Lipogenesis

More Related