Urine Concentration and Dilution PDF

Hi everyone. This is urine concentration and dilution. Uh, module three still, uh, gate in chapter 29. Kidneys have a tremendous capability to vary the relative proportions of solutes and water in the urine in response to changes in the body. When there is excess water in the body and osmolarity is reduced, the kidneys can excrete urine with osmolarity as low as $50 million, which is a concentration of about one sixth the osmolarity of normal body fluid. Conversely, when there is a deficit of body water and osmolarity is high, urine is highly concentrated with osmolarity of 1200 and $1,400 million per liter. At the same time, the kidneys can excrete a large volume of dilute urine or a small volume of concentrated urine without major changes in the rates of solute solute excretion. Antidiuretic hormone or vasopressin causes the kidneys to alter the excretion of water independent of solutes. When osmolarity of bodily fluids increases above normal, the posterior pituitary secretes more aids, which increases the water permeability of the distal tubules and collecting ducts. This alters the excretion of water and decreases urine volume, but does not change the excretion of solids. When there is excess water in the body, secretion of ADH by the posterior pituitary decreases, which reduces the permeability of the distal tubule and collecting ducts to water, and causes increased amounts of dilute urine to be excreted. When there's excess water in the body, the kidneys can excrete as much as 20l a day of dilute urine, with the concentration as low as $50 million per liter. Solutes are reabsorbed without re absorbing large amounts of water in the distal parts of the nephron, especially the late distal tubule and collecting ducts. 45 minutes after drinking one liter of water, the urine volume increases about six times normal. However, the total amount of solutes, uh remains the same. When this plasma passes through the glomerulus and becomes filtrate, its osmolarity is nearly the same as the plasma to excrete excess water. The filtrate is diluted as it passes along the tubule by reabsorbed solutes at a higher rate than water. This only occurs in certain segments, though. In the proximal tubules, solutes and water are reabsorbed in equal proportions, so little change in osmolarity occurs. Thus the filtrate remains iso osmotic as filtrate passes down to the descending loop of hennelly, water is reabsorbed by osmosis and the tubular fluid reaches equilibrium with the surrounding interstitial fluid of the renal medulla. The renal medulla is hypertonic. As I just circled here, uh, as compared to the original filtrate. Therefore, the tubular fluid becomes more concentrated as it flows into the inner medulla. In the ascending limo of the loop of Henley, especially the thick segment. Sodium potassium chloride or avidly reabsorbed. You can see this here graphically, um. However, it is impermeable to water even when Ada is present. Therefore, the tubular fluid becomes more dilute as it flows up the ascending loop of Henley. The osmolarity decreases from around 300 to 100 milliards moles per liter, regardless of his presence. Fluid leaving the distal tubular segment is hypo osmotic. You can see that here. So hyper osmotic. Uh, slightly hyper osmotic and then hypo osmotic. As the dilute fluid in the early distal tubule passes into the late distal convoluted tubule, cortical collecting ducts, and majorly collecting duct, there's reabsorption of sodium chloride. In the absence of ADHD, this portion of the tubule is also impermeable to water, and the additional reabsorption of solutes causes the tubular fluid to become even more dilute. Since water is not reabsorbed and solutes are, this leads to a large volume of dilute urine. The necklace. The mechanism for forming dilute urine is to continue reabsorption of solutes from the distal segments of the tubular system, while there's reduced water reabsorption. Fluid leaving the ascending loop of Hindley and the early distal tubule is always dilute regardless of aid levels. In the absence of Ach, the urine is further diluted in the distal tubule and collecting ducts and a large volume of urine and a dilute urine is excreted in the presence of Ach H. Though a large volume of water is reabsorbed and urine can be concentrated. Water is continuously lost from the body through these roots. Fluid intake is required to match this loss, but the kidneys have the ability to form a small volume of concentrated urine that minimizes the fluid intake that is required in order to form concentrated urine. Solutes are treated while increasing water reabsorption, which of course decreases urine volume. Human kidneys can produce a urine concentration of 1200 to 1400 milliliters, most which is 4 to 5 times the osmolarity of plasma. If the maximum urine concentrating ability is 1200 milli osmosis, the obligatory urine volume or the minimum volume of urine that must be excreted can be calculated using this formula here. In order to form concentrate urine, high levels of Aids must be present at age, increases the permeability of the distal tubules and collecting ducts to water, allowing for greater reabsorption. There is also. There also must be high osmolarity of the renal medullary interstitial fluid to provide an osmotic gradient for water absorption. The renal interstitial fluid is normally hyper osmotic, so when aid levels are high, water moves from the tubular membrane into the renal interstitium by osmosis. It is then carried back into the blood by the vasa rectum. The urine concentrating ability is limited by the levels of H and by the degree of hyper osmolality. Osmolarity of the renal medulla. The counter current multiplier mechanism is what creates the hyper osmolarity of the arena medulla. It is the special anatomical arrangement of the loops of hennelly and the vaso rectum. The osmolarity of the interstitial fluid, and most of the body is about 300 million moles per liter, which is similar to plasma osmolarity. The osmolarity. The medulla of the kidney is much higher and increases progressively to between 1200 to 1400 million moles. This means that the renal medullary interstitium accumulates solutes and greater excess of water. Once this concentration is achieved, it is maintained by the balance of inflow and outflow of solutes and water. The major factors that contribute to the buildup of solute concentration in the medulla are active transport of sodium and the Co transport of potassium chloride and other ions out of the thick portion of the ascending limb of the loop of Hindley. Uh two. Active transport of ions from the collecting ducts. Three. Facilitated diffusion of urea from the inner medullary collecting ducts into the interstitium, and for the diffusion of only small amounts of water from the medullary tubule tubules into the medullary interstitium. And we will go through this in more detail. A major reason for the high osmolarity of the loop of Henley is active transport of sodium, and the Co transport of potassium chloride and other ions from the thick ascending loop of Henley into the interstitium so thick ascending loop. Um. This pump is capable of establishing a 200 million Osmo concentration gradient. At the same time, the thick, ascending, and thin ascending limbs are virtually impermeable to water. Uh, opposite to this, the thick ascending is the, uh, descending loop of Henley, which is very permeable to water. Um, the tubular fluid osmolarity quickly equals the renal osmolarity as water diffuses out of the two below lumen and into the interstitium. Uh. So this is the, uh, descending loom here. This is the descending loom, which is very permeable to water. This is the ascending loom, which is impermeable to water and has the pump creating the concentration gradient and pumping, uh, solutes out. And this is the interstitium here in between. So now let's outline the steps in creating the hyper osmotic renal interstitium. To start with the fluid inside the renal tubule. Has a concentration of about 300 million smalls, which is the same, uh, that leaves the proximal tubule. The active ion pump in the thick ascending limb reduces the solute concentration inside the tubule and raises the interstitial concentration. So the active pump here and you can see this in step two. Um. This pump is limited to a 200ml more gradient. Uh, the tubular fluid in the descending limb quickly diffuses. So here's the descent limb. So on step three. Now, um, the two fluid in the descending limb quickly diffuses into the interstitium to create the equilibrium. Um. Then as additional fluid flows from the proximal tubule, um, it pushes this high prosthetic fluid into the ascending limb. So now this fluid that's been created been made, high osmotic is pushed around. You can see the arrow here. And for as it's pushed around the tubule, the ascending limb pumps ions out the same as we just discussed. So now it's created a greater concentration in the ascending limb. But this pump continues to pump ions out into the interstitium. Uh, and this creating that same 200 million Osmo concentration gradient. Uh, then once again, the descending limb fluid diffuses out of the descending limb. Uh, that raises the osmolarity of the dead inside the descending limb. To 500mg. Once again, fluid is pushed forward. Um, come back up here. Two steps for fluid is pushed forward, and the cycle continues. The overall net effect of this repeated process is adding more and more solutes to the renal interstitium, and increasing its osmolarity. Over time, this multiplies the concentration gradient, eventually raising the osmolarity of the interstitium to 1200 to 1400 million smalls. When the tubular fluid leaves the loop of Henley flowing in the distal convoluted tubule, the fluid is dilute with an awesome clarity of only about 100 to 140 million small. So this is in here. Uh, the early distal tubule further dilutes because it actively transports sodium out of the tubule but is impermeable to water. You can see that here. Um. As this dilute fluid flows into the cortical collecting tubule, the amount of water reabsorbed is dependent on the concentration of ADHD. In the absence of ADHD, this segment is almost impossible to water but continues to reabsorb solutes, causing further dilution. When there's a high concentration of ADHD, the cortical collecting tubule becomes highly permeable to water, where it rapidly absorbs where it is rapidly reabsorbed by the peri tubular capillaries. If you remember the period, tubular capillaries are, uh, flowing all around the loop of Henley. Uh, on page 324. There's a great image. Uh, because this water is reabsorbed in the cortex rather than the medulla. The osmolarity, the medulla is maintained as fluid continues along the major Leary collecting ducts. There's further water reabsorption, but in this area, the water reabsorbed is a relatively small amount and is rapidly carried away by the vas erector into the bloodstream. When there are high levels of Ach present and much more water is reabsorbed, the osmolarity the tubule fluid is nearly identical to the renal medulla, thus forming highly concentrated urine. Urea contributes about 50% of the osmolarity of the renal medullary interstitium. When the kidney is forming, maximally concentrated urine urea passively reabsorbed from the tubule. As water flows up the ascending loop of hennelly into the distal and cortical collecting tubules, little area is reabsorbed because these segments are impermeable to it. When at present water is reabsorbed rapidly and the urea concentration is increased in the intermediary collecting duct, urea diffuses out of the tubule and into the renal interstitial fluid. Diffusion is greatly facilitated by facilitated by the UT, A1 and UT T3 transporters, which are specific for urea. These transporters are activated by 80 H. ADHD activates these transporters, which allow for the diffusion of urea out of this tubule. Even though urea is being reabsorbed, concentrations remain high in the tubular fluid, which of course eventually forms urine, and therefore urinary excretion remains high of urea. Only small amounts of reabsorb of urea are reabsorbed in the thick limb of the loop of hennelly, the distal tubule and the cortical collecting duct, because they are less permeable to it. When aid is present. The UT, A1 and UTA three transporters cause urea to diffuse into the medulla interstitium, increasing the osmotic pressure of the renal medulla, helping to reabsorb water, which of course is the goal of ADHD, especially when ADHD levels are high when there's excess water in the body. Urine flow rate increases and urine concentration decreases, which of course decreases the interstitial osmotic gradient, causing more urine and urea to be excreted. A healthy person usually excretes 20 to 60% of the filtered urea. This is dependent upon urine flow rate and hydration. The rate of urine

Urine Concentration and Dilution PDF

Document Details

Tags

Related

Summary

Full Transcript

Upgrade to continue