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Osmoregulation and temperature regulation

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Here’s a fancy topic of the newer spec… I’ve never done the kidney so I spent my post-A levels life in total kidney ignorance and utter lack of knowledge of my urination habits and their complexity, oh what a fool I have been. You on the other hand are going to have the damn honour of actually having a clue about how the brain and the kidneys freshen our blood up all the time. Oh ye enlightened children, rise.


Osmoregulation refers to the control of water potential of the blood. The blood is complicated, it has all these ions and proteins and stuff. Cells use various things up all the time and some more often than others at different times, night, day, sweat, tears, etc.


There are systems in place that keep the blood at the right composition and pressure. The hypothalamus and posterior pituitary in the brain release a hormone into the blood that reaches the kidney and enables its cells to take up more water, to prevent it being wasted in urine as the case may be. This is detected by osmoreceptors.


The hormone is known as vasopressin or antidiuretic hormone (ADH), has a very short half life of 16-24 minutes as you can imagine since it regulates fast-changing things like water retention and blood pressure. It acts in the negative feedback loop that maintains optimal plasma concentration.


More specifically, the hypothalamus synthesises it while the posterior pituitary which is actually an extension of the hypothalamus, stores it for release into the blood.



ADH stimulates water retention by the kidney by:


1. Increasing water permeability in a part of the kidney cell which results in retaining more water and excreting more concentrated urine

2. Increasing urea permeability by another part of the kidney cell which results in its concentration in the urine

3. Increasing sodium absorption across the section of the kidney cell which circulates the solution, resulting in reabsorption of water


This uses the principles of osmosis where water moves from a higher water potential (less concentrated solution) to a lower water potential (more concentrated solution). Here urea is the solute and water is the solvent. Guess the solution! …pee.


Ok let’s look at the actual kidney cell and all this mystery of the different “parts” that do different things.


The nephron

The cell in the kidney that executes all this action is the nephron. It looks a bit weird and has all these tubes hanging off it. A kidney has about a million of these bad boys.


The path that the fluid takes via the nephron and to becoming urine is threefold: filtration, reabsorption and secretion. This means that there is a middle section that allows for reabsorption into the bloodstream before releasing the contents into urine.



Oooh almost got poked by that loop of Henle… keep to yourself loop.


Let’s start at the top with the glomerulus. It’s a scrunched up bunch of capillaries that allow the high pressure needed to filter the blood forwards. The fluid passes from the capillaries into the capsule that surrounds them, Bowman’s capsule.

Oooh creepy. This is where the subsequent glomelural filtrate is formed. Still similar to blood plasma, but minus all those proteins and large molecules.


Next, water and glucose are reabsorbed by the proximal convoluted tubule (in yellow)… At least it’s honest about being convoluted. Unlike the distal convoluted tubule, it doesn’t have many mitochondria. The distal convoluted tubule needs many mitochondria to generate ATP for active transport of ions such as sodium ions back from the filtrate. As the useful minerals get absorbed back into circulation, waste materials such as urea accumulate in the fluid (urea is produced in the liver from excess amino acids by joining two ammonia molecules with one carbon dioxide molecule in what is termed the ornithine cycle).


For the water to be reabsorbed, a countercurrent exchange system needs to exist. This is provided by the loop of Henle which has a downwards part and an upwards part. The upwards part is impermeable to water, enabling the countercurrent exchange and the pumping out of the sodium ions.



Its job is to maintain a gradient of sodium ions to enable the water potential gradient underpinning water movement and reabsorption. This is carried away in the distal tubule and collecting ducts. The water and waste is then excreted via urine.


The kangaroo rat lives in a dry environment

This lil fella is an adorbsssss little mammal that lives in North America in very dry/desert-type areas. It is a master at preserving its water, and can live without ever actually drinking water at all. Some of its adaptations are behavioural such as being inactive during the day and being active at night when it’s colder, as well as burrowing into sand, and bathing in sand to keep its hairs free of too much oil which would decrease their ability to insulate the body.



Other adaptations regard the kidney itself, specifically very long loops of Henle. They allow longer filtration processes to take place, which allows as much water as possible, to the extreme, to be reabsorbed. Their urine is very small in volume and extremely concentrated in urea, up to 10 times more concentrated than a human’s.


They also obtain water from their metabolic oxidation reactions in cells, up to 90% of all their water. The remainder comes from food such as seeds. Oh, and by the way, if they weren’t adorable enough already – they’re called kangaroo rats because they jump like a kangaroo, can you imagine??


Temperature regulation



Not all organisms maintain their body’s core temperature the same way. Some control it internally like we do. We’re endothermic. Reptiles for example are not. They’re ectothermic. Two pennies for who guesses how these fine specimens maintain their temperature. Do they:


A) Run for heat?
B) Shiver for heat?
C) Sit where the sun shines?


They sit where the sun shines, ladies and gentlemen, they just sit there until it gets too hot. And what do they do when it gets too hot? Well, funny you should ask. They move their scaly little selves to a shady place. Why didn’t our monkey-faced ancestors think of that? (They did, long story.)


Needless to say, a lot of ectothermic organisms live in extremely stable regions where temperature doesn’t fluctuate wildly.


Fun fact: that bit in the brain, the hypothalamus, is responsible for temperature homeostasis. Thermoreceptors pick up increases and decreases in optimal body temperature and send signals to effectors to act. This is what happens:


Too hot

Sweat cools down the body by producing water that upon evaporation removes heat energy.

Vasodilation is the dilation of blood vessels. It results in the distance between them and the skin shortening so that excess heat can dissipate quicker. Flat hairs ensure that no air is trapped close to the skin. Air is a poor heat conductor so effectively this removes any potential insulation.


Too cold

No sweat occurs. Vasoconstriction has the opposite effect to vasodilation, as the vessels tighten up instead of dilate to prevent heat loss. Raised hairs create a layer of air trapped between hairs and skin, minimising heat loss to the environment. Shivering causes muscles to do work, thus releasing more heat. Hormones like adrenaline may be released to increase metabolism.





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