Fats and lipids

Last updated: February 06, 2023

Fats and lipids

anatomy

anatomy

Bones and joints of the thoracic wall
Muscles of the thoracic wall
Vessels and nerves of the thoracic wall
Anatomy of the breast
Anatomy of the pleura
Anatomy of the lungs and tracheobronchial tree
Anatomy of the heart
Anatomy of the coronary circulation
Anatomy of the superior mediastinum
Anatomy of the inferior mediastinum
Anatomy clinical correlates: Thoracic wall
Anatomy clinical correlates: Breast
Anatomy clinical correlates: Pleura and lungs
Anatomy clinical correlates: Heart
Anatomy clinical correlates: Mediastinum
Anatomy of the anterolateral abdominal wall
Anatomy of the abdominal viscera: Blood supply of the foregut, midgut and hindgut
Anatomy of the abdominal viscera: Esophagus and stomach
Anatomy of the abdominal viscera: Small intestine
Anatomy of the abdominal viscera: Large intestine
Anatomy of the abdominal viscera: Pancreas and spleen
Anatomy clinical correlates: Anterior and posterior abdominal wall
Anatomy of the pelvic girdle
Anatomy of the pelvic cavity
Bones of the vertebral column
Bones of the lower limb
Fascia, vessels and nerves of the upper limb
Anatomy of the anterior and medial thigh
Muscles of the gluteal region and posterior thigh
Vessels and nerves of the gluteal region and posterior thigh
Anatomy of the popliteal fossa
Anatomy of the leg
Anatomy of the foot
Anatomy of the hip joint
Anatomy of the knee joint
Anatomy of the tibiofibular joints
Joints of the ankle and foot
Bones of the upper limb
Anatomy of the brachial plexus
Anatomy of the pectoral and scapular regions
Anatomy of the arm
Muscles of the forearm
Vessels and nerves of the forearm
Muscles of the hand
Anatomy of the sternoclavicular and acromioclavicular joints
Anatomy of the glenohumeral joint
Anatomy of the elbow joint
Anatomy of the radioulnar joints
Joints of the wrist and hand
Anatomy clinical correlates: Clavicle and shoulder
Anatomy clinical correlates: Axilla
Anatomy clinical correlates: Arm, elbow and forearm
Anatomy clinical correlates: Wrist and hand
Anatomy clinical correlates: Median, ulnar and radial nerves
Major depressive disorder
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Mood disorders: Pathology review
Amnesia, dissociative disorders and delirium: Pathology review
Personality disorders: Pathology review
Eating disorders: Pathology review
Psychological sleep disorders: Pathology review
Psychiatric emergencies: Pathology review
Drug misuse, intoxication and withdrawal: Hallucinogens: Pathology review
Selective serotonin reuptake inhibitors
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Atypical antidepressants
Lithium
Nonbenzodiazepine anticonvulsants
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Anticonvulsants and anxiolytics: Barbiturates
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Psychomotor stimulants
Glycolysis
Citric acid cycle
Electron transport chain and oxidative phosphorylation
Gluconeogenesis
Glycogen metabolism
Pentose phosphate pathway
Physiological changes during exercise
Amino acid metabolism
Nitrogen and urea cycle
Fatty acid synthesis
Fatty acid oxidation
Ketone body metabolism
Cholesterol metabolism
Glucose-6-phosphate dehydrogenase (G6PD) deficiency
Lactose intolerance
Glycogen storage disease type I
Glycogen storage disease type II (NORD)
Leukodystrophy
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Gaucher disease (NORD)
Niemann-Pick disease types A and B (NORD)
Niemann-Pick disease type C
Fabry disease (NORD)
Tay-Sachs disease (NORD)
Mucopolysaccharide storage disease type 1 (Hurler syndrome) (NORD)
Mucopolysaccharide storage disease type 2 (Hunter syndrome) (NORD)
Cystinosis
Phenylketonuria (NORD)
Cystinuria (NORD)
Homocystinuria
Maple syrup urine disease
Familial hypercholesterolemia
Hypertriglyceridemia
Disorders of carbohydrate metabolism: Pathology review
Disorders of fatty acid metabolism: Pathology review
Dyslipidemias: Pathology review
Glycogen storage disorders: Pathology review
Lysosomal storage disorders: Pathology review
Carbohydrates and sugars
Fats and lipids
Proteins
Folate (Vitamin B9) deficiency
Vitamin B12 deficiency
Wernicke-Korsakoff syndrome
Fat-soluble vitamin deficiency and toxicity: Pathology review
Zinc deficiency and protein-energy malnutrition: Pathology review
Cellular structure and function
Cell membrane
Selective permeability of the cell membrane
Extracellular matrix
Cell-cell junctions
Endocytosis and exocytosis
Osmosis
Resting membrane potential
Nernst equation
Cytoskeleton and intracellular motility
Cell signaling pathways
Adrenoleukodystrophy (NORD)
Zellweger spectrum disorders (NORD)
Alport syndrome
Ehlers-Danlos syndrome
Marfan syndrome
Peroxisomal disorders: Pathology review
Nuclear structure
DNA structure
Transcription of DNA
Translation of mRNA
Amino acids and protein folding
Nucleotide metabolism
DNA replication
Lac operon
DNA damage and repair
Cell cycle
Mitosis and meiosis
DNA mutations
Lesch-Nyhan syndrome
Adenosine deaminase deficiency
Purine and pyrimidine synthesis and metabolism disorders: Pathology review
Polymerase chain reaction (PCR) and reverse-transcriptase PCR (RT-PCR)
Gel electrophoresis and genetic testing
ELISA (Enzyme-linked immunosorbent assay)
Karyotyping
DNA cloning
Fluorescence in situ hybridization

Transcript

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Content Reviewers

Rishi Desai, MD, MPH,Yifan Xiao, MD

Fats are an essential part of a healthy diet. They contribute to the taste and texture of foods, like the smoothness of guacamole and the flakiness of a croissant. Fats are also a major source of energy and a critical component of cells and tissues, and they also help absorb essential vitamins, and can be converted into other molecules like prostaglandins which help cells communicate with each other.

Fats have a three-carbon backbone called glycerol, as well as fatty acid chains. The fatty acid chain is basically a string of carbon and hydrogen atoms. When an “OH” group from the glycerol molecule binds to a Hydrogen from the fatty acid, an “H20” or a water molecule - gets released, and the two molecules link up.

If this happens once, the result is a monoglyceride. If it happens twice, it’s a diglyceride, and three times makes a triglyceride.

Now, there are various types of fatty acid chains, and one way to categorize them is by their length, in other words, how many carbons they have. Short chain fatty acids have 2 to 5 carbons, medium chain fatty acids have 6 to 12 carbons, and long chain fatty acids have 13 or more carbons.

Fatty acid chains are also categorized by the bonds connecting the carbons in the chain. A single bond is just one bond between the carbon atoms, and when a fatty acid chain has only single bonds, it’s called a saturated fatty acid - because it has as many hydrogen atoms as possible or it’s saturated with them.

Triglycerides with saturated fatty acids are nice and straight so they pack together really well, and as a result they’re usually solid at room temperature. And the longer the saturated fatty acid chain, the more likely it will be solid at room temperature.

Carbons can also have double bonds between them though, and when a fatty acid has one or more double bonds, it’s called an unsaturated fatty acid because it’s not saturated with hydrogen atoms - for every double bond there are two fewer hydrogen atoms. Also, a double bond causes a kink in the molecule so the unsaturated fats don’t pack together as nicely as saturated fats. As a result, unsaturated fats are usually liquid at room temperature.

Unsaturated fatty acids can be further classified, according to the number of their double bonds. Monounsaturated Fatty acids are unsaturated fatty acids with just one double bond. Polyunsaturated fatty acids have two or more double bonds.

Also, they can be classified according to their location as well, since all these hydrogens can get kinda crazy-looking, we’ll just take them away for now. So, another name for the methyl end is the omega end, and then we can count the number of carbons until the first double bond. Since this one’s three, it would be an omega-3 fatty acid. If the double bond is 6 carbons from the end, it’s omega-6, and if it’s 9 carbons from the end, it’s called omega-9.

Now, to make things even easier when looking at these molecules, I’m just going to show the bonds. Alright, so omega 3’s are usually polyunsaturated fatty acids, and include alpha-linolenic acid, or ALA, eicosapentaenoic acid, or EPA, and docosahexaenoic acid, or DHA.

EPA and DHA are marine sources of omega-3’s. They’re produced by microalgae, and end up in the tissues of fish like anchovies, mackerel, salmon, and sardines. ALA is found in plants like flaxseed, walnuts, and canola and soybean oils. Our bodies can convert ALA into EPA and DHA, but it’s an inefficient process that yields only small quantities, and that’s why dietary recommendations include foods that have EPA and DHA.

Omega-6 fatty acids are also usually polyunsaturated, and include linoleic acid and arachidonic acid. Linoleic acid is found in oils like safflower, corn, and soybean oils. Arachidonic acid is found in animal sources like fish, meat, and eggs. Our bodies can convert linoleic acid into arachidonic acid, but once again the process is inefficient. Because ALA and linoleic acid can only be obtained in the diet, they are considered essential fatty acids.

Omega-9 fatty acids are typically monounsaturated fatty acids, and an example would be Oleic acid, and these can be made by the human body. Foods like canola and olive oil, as well as almonds contain omega-9s.

Now, looking at the double bond of this unsaturated fatty acid, like most unsaturated fats, it’s got a cis configuration. In a cis configuration, the two functional groups are on the same side of the double-bonded carbons. Now when this happens, the fatty acid chain naturally bends. A molecule that bends does not pack tightly together, so it’s a lot more fluid - think about cooking oils, which are liquid at room temperature.