The structure of the liver:p1
- Liver cells or hepatocytes have large nuclei, prominent Golgi apparatus, and lots of mitochondria, indicating that they are metabolically active cells
- They divide and replicate - even if around 65% of the liver is lost, it will regenerate in a matter of months.
- The blood from the hepatic artery and the hepatic portal vein is mixed in spaces called sinusoids which are surrounded by hepatocytes.
The structure of the liver:p2
- This mixing increases the oxygen content of the blood from the hepatic portal vein, supplying the hepatocytes with enough oxygen for their needs.
- The sinusoids contain Kupffer cells, which act as the resident macrophages of the liver, ingesting foreign particles and helping to protect against disease.
- The hepatocytes secrete bile from the breakdown of the blood into spaces called canaliculi, and from these the bile drains into the bile ductules which take it to the gall bladder.
structure of the liver diagram
The functions of the liver:
The liver has many functions - around 500 different metabolic pathways are linked to the liver.
Several of these play a major role in homeostasis:
Carbohydrate metabolism:
Deamination of excess amino acids:
Detoxification
Carbohydrate metabolism:
- Hepatocytes are closely involved in the homeostatic control of glucose levels in the blood by their interaction with insulin and glucagon.
- When blood glucose levels rise, insulin levels rise and stimulate hepatocytes to convert glucose to the storage carbohydrate glycogen.
- About 100g of glycogen is stored in the liver.
- Similarly, when blood sugar levels start to fall, the hepatocytes convert the glycogen back to glucose under the influence of the hormone glucagon.
Deamination of excess amino acids:
p1
- The liver plays a vital role in protein metabolism where hepatocytes synthesise most of the plasma proteins.
- Hepatocytes also carry out transamination - the conversion of one amino acid into another.
- This is important because the diet does not always contain the required balance of amino acids but transamination can overcome the problems this might cause.
- The most important role of the liver in protein metabolism is in deamination - the removal of an amine group from a molecule.
- The body cannot store either proteins or amino acids.
- Any excess ingested protein would be excreted and therefore wasted if it were not for the action of the hepatocytes.
Deamination of excess amino acids:
p2
- They deaminate the amino acids, removing the amino group, and converting it first into ammonia which is very toxic and then to urea.
- Urea is toxic in high concentrations but not in the concentrations normally found in the blood.
- Urea is excreted by the kidneys
- The remainder of the amino acid can then be fed into cellular respiration or converted into lipids for storage.
- The ammonia produced in the deamination of proteins is converted into urea in a set of enzyme-controlled reactions known as the ornithine cycle.
- Removing the amino group from amino acids and converting the highly toxic ammonia to the less toxic and more manageable compound urea involves some complex biochemistry.
diagram of deamination
ornithine cycle diagram
During this cycle, one molecule of urea is produced from one molecule of carbon dioxide and two amino groups (from two amino acids)
The urea diffuses through the phospholipid bilayer of the membranes of the hepatocytes and is then transported to the kidneys dissolved in the blood plasma
Detoxification
p1
- The level of toxins in the body always tends to increase.
- Apart from urea, many other metabolic pathways produce potentially poisonous substances.
- We also take in a wide variety of toxins by choice such as alcohol and other drugs.
- The liver is the site where most of these substances are detoxified and made harmless.
- One example is the breakdown of hydrogen peroxide, a by-product of various metabolic pathways in the body.
- Hepatocytes contain the enzyme catalase, one of the most active known enzymes, that splits the hydrogen peroxide into oxygen and water.
Detoxification
p2
Another example is the way in which liver detoxifies the ethanol - the active drug in alcoholic drinks.
Hepatocytes contain the enzyme alcohol dehydrogenase that breaks down the ethanol to ethanal.
Ethanal is then converted to ethanoate which may be used to build up fatty acids or used in cellular respiration.
liver cells under microscope
liver cells under microscope more detail - hepatocytes
Cirrhosis of the liver:
Cirrhosis is a disease where the normal liver tissue is replaced by fibrous scar tissue.
There are lots of different causes including genetic conditions and hepatitis C, however, in the UK the most common cause is drinking excessive amounts of alcohol.
There are three stages of alcoholic liver disease - alcoholic fatty liver disease, alcoholic hepatitis, and liver cirrhosis.
In fatty liver, big fat-filled vesicles displace the nuclei of the hepatocytes and the liver gets larger.
alcoholic hepatitis,
the patient has fatty liver along with damaged hepatocytes and the sinusoids and hepatic veins become narrowed.
In alcoholic cirrhosis the liver tissue is irreversibly damaged. Many hepatocytes die and are replaced with fibrous tissue.
The hepatocytes can no longer divide and replace themselves so the liver shrinks and its ability to deal with toxins in the body decreases.
What are kidneys
Human kidneys are typical of all mammalian kidneys.
They are a pair of reddish-brown organs attached to the back of the abdominal cavity.
They are usually surrounded by a thick, protective layer of fat and a layer of fibrous connective tissue.
The kidneys play two important homeostatic roles in the body -
excretion and osmoregulation.
They filter nitrogenous waste products out of the blood, especially urea.
They also help to maintain the water balance and pH of the blood, and hence the tissue fluid that surrounds all the cells.
The anatomy of the kidneys:
p1
- The kidneys are supplied with blood at arterial pressure by the renal arteries that branch off from the abdominal aorta.
- Blood that has circulated through the kidneys is removed by the renal vein that drains into the inferior vena cava.
- About 90-120cm’ of blood passes through the kidneys every minute.
- All of the blood in the body passes through the kidneys about once an hour.
- The kidneys filter 180 dm of blood a day, producing 1-2 dm of urine.
- The final volume depends on many different factors.
The anatomy of the kidneys:
p2
The kidneys are made up of millions of small structures called nephrons that act as filtering units.
The sterile liquid produced by the kidney tubules is called urine.
The urine passes out of the kidneys down tubes called ureters.
It is collected in the bladder, a muscular sac that can store around 400-600 cm’ of urine.
When the bladder is getting full, the sphincter at the exit to the bladder opens and the urine passes out of the body down the urethra.
kidney location diagram
Kidney structure:
three main areas
- the cortex, the medulla, and the pelvis
The cortex
is the dark outer layer.
This is where the filtering of the blood takes place and it has a very dense capillary network carrying the blood from the renal artery to the nephrons.
The medulla
is lighter in colour
it contains the tubules of the nephrons that form the pyramids of the kidney and the collecting ducts.
The pelvis
is the central chamber where the urine collects before passing out down the ureter.
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chapter 2 part 132
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chapter 2 part 232
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chapter 2 part 328
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chapter 2 part 418
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chapter 439
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chapter 4 part 231
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chapter 5 part 134
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chapter 5 part 221
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chapter 17 p232
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chapter 2145
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chapter 21 part 2 COPY15
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chapter 21 part 319
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chapter 21 part 3 COPY19
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chapter 7 p120
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chapter 7 pt 224
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Chapter 7 p 414
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chapter 16 pt 118
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chapter 16 pt 219
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chapter 16 pt 316
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chapter 16 pt 415
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chapter 16 pt 514
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chapter 13 p139
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chapter 13 p228
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chapter 14 p125
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chapter 1426
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chapter 19 p126
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chapter 19 p224
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chapter 19 p321
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chapter 15 pt25
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chapter 15 p228
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chapter 15 p335
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chapter 15 p426
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chapter 8 p332
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chapter 3 p132
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chapter 11 p244
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chapter 10 p331
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chapter 10 p526
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chapter 12 p129
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chapter 12 p430
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chapter 20 p126
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chapter 20 p232
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chapter 20 p338
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chapter 20 p428
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chapter 23 P133
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Chapter 23 P226
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Chapter 23 P318
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Chapter 23 P413
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MATHS FORMULAE38
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Chapter 24 P123
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Chapter 24 P230
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Chapter 24 P324
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Chapter 24 P416
