What is the function of the glomerular capillaries?

The glomerular capillaries act as a filtering structure where blood pressure forces water and solutes out of the blood and into the Bowman's capsule.

What is the role of the proximal convoluted tubule?

The proximal convoluted tubule is involved in reabsorbing a large portion of water, sodium, potassium, chloride, and other substances into the bloodstream.

How does the loop of Henle contribute to kidney function?

The loop of Henle uses a counter-current multiplier mechanism to make the medulla salty, allowing water to be reabsorbed in the descending limb.

What hormone regulates calcium reabsorption in the distal convoluted tubule?

Calcium reabsorption in the distal convoluted tubule is regulated by the parathyroid hormone.

What is urea recycling and its importance?

Urea recycling refers to the process where urea is reabsorbed from the collecting duct to enhance medullary interstitial gradient, promoting water reabsorption.

What structures compose a nephron?

A nephron consists of the glomerulus, Bowman's capsule, proximal convoluted tubule, loop of Henle, distal convoluted tubule, and collecting duct.

What effect does aldosterone have on the distal convoluted tubule?

Aldosterone increases sodium reabsorption and potassium secretion in the distal convoluted tubule.

How does antidiuretic hormone (ADH) work in the nephron?

ADH increases water reabsorption by inserting aquaporin channels in the collecting duct and the late distal tubule.

Renal | Filtration, Reabsorption, and Secretion: Overview

00:36:38

https://www.youtube.com/watch?v=rwZIT_N75Bs

Sintesi

TLDRThis video provides a comprehensive overview of kidney function with a focus on the nephron. It covers the entire process from glomerular filtration through to collecting duct activities, discussing pressure dynamics, filtration rates, and hormonal influences. Key structures in the nephron like the proximal convoluted tubule, loop of Henle, and distal convoluted tubule are examined, as well as their roles in electrolyte balance, water reabsorption, and urine concentration. Hormonal regulation by aldosterone, parathyroid hormone, and antidiuretic hormone is also reviewed, explaining their effects on calcium and sodium reabsorption, and osmoregulation. Concepts like counter-current exchange and urea recycling are explored to showcase the nephron's role in maintaining the body's fluid and electrolyte balance.

Punti di forza

🔬 The nephron is the functional unit of the kidney.
💧 The proximal convoluted tubule reabsorbs most water and essential nutrients.
🔄 The loop of Henle creates a concentration gradient for water reabsorption.
✨ The distal convoluted tubule and collecting duct fine-tune urine concentration.
⚛️ Aldosterone and ADH regulate ion exchanges and water balance.
🌀 Urea recycling enhances the medullary concentration gradient.
📉 The glomerular filtration rate is linked to systemic blood pressure.
⚠️ Hormones like ADH and aldosterone are critical for osmoregulation.
🧬 Calcium reabsorption is significantly influenced by parathyroid hormone.
🔗 Effective fluid regulation in kidneys prevents electrolyte imbalances.

Linea temporale

00:00:00 - 00:05:00
The video provides an overview of the renal system, covering topics such as the proximal convoluted tubule, glomerular filtration, Henle's loop, distal convoluted tubule, and collecting duct. The initial focus is on key pressures involved in glomerular filtration including glomerular hydrostatic pressure, capsular hydrostatic pressure, and the role of plasma proteins.
00:05:00 - 00:10:00
The discussion moves into detailed processes occurring in the proximal convoluted tubule where a significant amount of reabsorption happens. Sodium, water, and other solutes like potassium, chloride, magnesium, calcium, and bicarbonate are reabsorbed here. Glucose and amino acids are also reabsorbed through co-transport with sodium. Also, small proteins and lipids are reabsorbed while metabolic wastes and some drugs are secreted.
00:10:00 - 00:15:00
The loop of Henle is then discussed, highlighting the countercurrent multiplier system in the nephron. Water reabsorption is concentrated in the descending limb due to the salty medullary interstitial space created by the ascending limb's active solute transport. The osmolality gradient is emphasized as it increases medially from cortex to medulla.
00:15:00 - 00:20:00
Attention is given to the osmolality changes as fluids pass through the nephron segment. Proximal tubule reabsorbs up to 65% water and sodium leading to isotonicity, while descending limb loses water to hypertonicity. The ascending limb impacts osmolality by reabsorbing solutes, thus producing diluted filtrate by the distal convoluted tubule.
00:20:00 - 00:25:00
The distal convoluted tubule's role is refined by hormonal influences such as parathyroid hormone and aldosterone, affecting reabsorption processes for calcium and sodium. The production and regulation of hormones like antidiuretic hormone are noted for their effects on collecting duct water reabsorption, affecting blood volume and pressure.
00:25:00 - 00:30:00
Collecting duct processes involving sodium reabsorption and balancing of potassium via aldosterone are examined. Antidiuretic hormone's role in managing water balance continues in the collecting duct affecting blood osmolality and pressure. This section emphasizes the physiological and hormonal controls over kidney functions.
00:30:00 - 00:36:38
Finally, metabolic wastes such as creatinine and urea handling in collecting ducts are discussed alongside tubular secretion aspects. The concept of urea recycling contributes to the medullary osmolarity, enhancing water reabsorption from descending limb and concentrating urine. The segment concludes summarizing kidney function efficiencies and physiological balance control discussed throughout the course.

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Mappa mentale

Domande frequenti

What is the function of the glomerular capillaries?
The glomerular capillaries act as a filtering structure where blood pressure forces water and solutes out of the blood and into the Bowman's capsule.
What is the role of the proximal convoluted tubule?
The proximal convoluted tubule is involved in reabsorbing a large portion of water, sodium, potassium, chloride, and other substances into the bloodstream.
How does the loop of Henle contribute to kidney function?
The loop of Henle uses a counter-current multiplier mechanism to make the medulla salty, allowing water to be reabsorbed in the descending limb.
What hormone regulates calcium reabsorption in the distal convoluted tubule?
Calcium reabsorption in the distal convoluted tubule is regulated by the parathyroid hormone.
What is urea recycling and its importance?
Urea recycling refers to the process where urea is reabsorbed from the collecting duct to enhance medullary interstitial gradient, promoting water reabsorption.
What structures compose a nephron?
A nephron consists of the glomerulus, Bowman's capsule, proximal convoluted tubule, loop of Henle, distal convoluted tubule, and collecting duct.
What effect does aldosterone have on the distal convoluted tubule?
Aldosterone increases sodium reabsorption and potassium secretion in the distal convoluted tubule.
How does antidiuretic hormone (ADH) work in the nephron?
ADH increases water reabsorption by inserting aquaporin channels in the collecting duct and the late distal tubule.

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Sottotitoli

Scorrimento automatico:

00:00:06
all right ninja nerds in this video
00:00:08
we're going to take a nice brief
00:00:09
overview of everything that we've
00:00:10
covered throughout the series of videos
00:00:12
in the renal playlist so you guys have
00:00:14
already watched it about the proximal
00:00:15
convoluted tubule you guys have watched
00:00:17
the glomerular filtration process the
00:00:19
loop of Henle the distal convoluted
00:00:21
tubule and the collecting duct videos
00:00:22
then what we're going to do is we're
00:00:24
going to take a nice little brief
00:00:24
overview over that just to make sure
00:00:26
that we got all of this stuff clear
00:00:27
alright so let's go ahead and start that
00:00:29
so if you guys remember what do we say
00:00:31
what's happening well we said that this
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was the a fairy material right coming in
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to the actual glomerulus and the glue
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Maris was that set of capillaries that
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was the filtering structure right and
00:00:40
what did we say here was happening we
00:00:42
said there was a mixture of pressures
00:00:43
right the pressures that was trying to
00:00:45
push out was the glomerular hydrostatic
00:00:46
pressure which is inside of the
00:00:48
capillaries exerted by what the blood
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pressure the systemic blood pressure
00:00:51
then what else do we say we also said
00:00:54
that there was an osmotic pressure of
00:00:56
the AAB specifically the proteins with
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inside the actual blood then we're
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trying to pull water into the blood
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stream then we said that there was a
00:01:04
capsular hydrostatic pressure that was
00:01:05
actually going to be due to the filtrate
00:01:07
trying to drain sometimes some of that
00:01:09
filtrate can back up and exert a
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pressure trying to push certain filtrate
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back into the actual maelys that was
00:01:15
called the capsular hydrostatic pressure
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and then we say that there was a
00:01:18
capsular osmotic pressure but it should
00:01:21
be zero because there should be no
00:01:23
proteins plasma proteins like albumin
00:01:24
that should be filtered across this
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membrane because if you remember the
00:01:28
capsular osmotic pressure was trying to
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pull fluid out into the glomerulus space
00:01:31
alright so now that we know all of those
00:01:33
again we remember what was the overall
00:01:35
outcome of this we said that there
00:01:38
should be a net filtration pressure of
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approximately ten millimeters of mercury
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right we said that that's what it should
00:01:44
be the net filtration pressure should be
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approximately about ten millimeters of
00:01:48
mercury what else do we say remember
00:01:50
that relationship we made with net
00:01:52
filtration pressure we said the net
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filtration pressure was directly
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proportional to the glomerular
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filtration rate and we said that the
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glomerular filtration rate should
00:02:00
approximately be about 125 milliliters
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per minute we did that calculation in
00:02:07
the glomerular filtration video so that
00:02:09
is our GFR the glomerular filtration
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rate
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which is directly proportional to the
00:02:15
net filtration pressure is how much
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fluid in volume per time is being
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filtered across this actual glomerular
00:02:22
filtration membrane and we said a lot of
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different fluids are being pressed
00:02:26
across this membrane right before we do
00:02:28
that though what was this actual
00:02:29
arterial here supplying the glomerulus
00:02:31
do you guys remember this was the a
00:02:33
ferrant arteriole right and we said that
00:02:39
this was one of the weird example of a
00:02:40
body that in a capillary bed was
00:02:42
actually fed bar inner cereal and then
00:02:44
drained by an arteriole so this is an
00:02:46
example of a efferent arteriole because
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this is actually draining the actual
00:02:52
capillary but then what do we say this
00:02:56
filtration process occurs across the
00:02:57
membrane a lot of fluid and a lot of
00:02:59
different different types of filtrate
00:03:00
substances are actually going to be
00:03:02
accumulated across this area and drained
00:03:05
into this next structure here what is
00:03:07
this next structure here we said that
00:03:09
this is the proximal convoluted tubules
00:03:12
and this is one of the more important
00:03:14
sites of the actual nephron what is a
00:03:16
nephron you guys remember we said in
00:03:17
Efron was the glomerular capillaries
00:03:20
plus the Bowman's capsule right which is
00:03:23
made up with a visceral layer which is
00:03:24
the podocytes
00:03:25
and the parietal layer which is made up
00:03:27
of those simple squamous epithelial
00:03:28
cells that made up the renal corpuscle
00:03:30
plus the proximal convoluted tubule the
00:03:34
loop of Henle and the distal convoluted
00:03:35
tubule that was a nephron and we have
00:03:37
about 1.2 million in one kidney so if we
00:03:39
have two of them generally unless you
00:03:41
have renal agenesis unilateral generally
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you're going to have two kidneys and
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it's gonna be about 2.4 million right so
00:03:47
that's pretty cool anyway we get the
00:03:49
proximal convoluted tubules what did we
00:03:50
say happens in this area a lot of
00:03:52
reabsorption a lot let's start with that
00:03:54
first and then we'll talk about the
00:03:55
secretion mechanisms so we said a lot of
00:03:58
sodium was reabsorbed here we said a lot
00:04:01
of water was reabsorbed here we said a
00:04:04
lot of potassium was reabsorbed here a
00:04:06
lot of chloride a lot of magnesium
00:04:11
decent amount of calcium is reabsorbed
00:04:13
here and what else did we say was very
00:04:15
absorbed here bicarbonate so exactly
00:04:19
about how much of these guys there was
00:04:21
more will mention a couple of other ones
00:04:23
right but sodium about 65% of the actual
00:04:27
sodium
00:04:27
reabsorbed what do we say was really
00:04:29
important about that we said that
00:04:32
because 65 percent of the sodium is
00:04:34
reabsorbed water-filled obliged to
00:04:36
follow and we said that that we
00:04:38
approximately about 65 percent we said
00:04:42
bicarb generally depending upon the
00:04:43
body's demands generally about 90% of
00:04:47
the bicarb is reabsorbed about 85 to 90
00:04:49
percent magnesium it's kind of
00:04:52
questionable certain literature will say
00:04:54
different we're just going to say it's
00:04:55
question about the amounts of magnesium
00:04:57
that are going to be reabsorbed
00:04:58
potassium is around the range of about
00:05:02
60% okay around the range of about 60%
00:05:05
and chloride ranges to about 50 to 60%
00:05:08
also all right calcium about 60% of the
00:05:13
calcium is reabsorbed here we said right
00:05:14
60% of the calcium is reabsorbed here a
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lot of different things reabsorbed here
00:05:18
and again what is the definition of
00:05:20
tubular reabsorption we said tubular
00:05:23
reabsorption is defined as the process
00:05:26
in which substances from the actual
00:05:27
kidney tubules this filtrate is moving
00:05:30
where we said that these substances are
00:05:33
moving from the actual kidney tubules
00:05:36
where into the blood all right from the
00:05:40
kidney tubules and into the blood so if
00:05:42
this sodium is moving this area this
00:05:43
water is moving to this area this bicarb
00:05:45
is moving to this area and the magnesium
00:05:48
and the potassium and they're going into
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the blood this is defined as tubular
00:05:52
reabsorption we talked about many of the
00:05:54
mechanisms how sodium is brought in how
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water how by car we're not going to do
00:05:58
that we don't need to write but one
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thing I do want to mention is what
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actually is brought in with sodium and
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what is also going to be another process
00:06:06
talking about just a second remember
00:06:07
glucose one of the organic nutrients and
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amino acids amino acids these substances
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did what remember they actually went
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with sodium the sodium glucose and
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sodium amino acid code transport
00:06:22
mechanisms those were also important so
00:06:24
glucose and amino acids were also
00:06:28
reabsorbed in this process dependent
00:06:30
upon the actual presence of sodium we
00:06:32
said what else do we say gets reabsorbed
00:06:34
small amounts of your real gets
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reabsorbed let's use this
00:06:39
actual green colors in urea so urea
00:06:43
about 50% about 50% of the urea is
00:06:48
actually going to get reabsorbed into
00:06:50
the body right back into the bloodstream
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oh good question how much of the glucose
00:06:54
in amino acids physiologically should be
00:06:56
100% if you have traces of glucose in
00:07:02
the air and they call that glucose area
00:07:03
right and usually glucose urea is
00:07:05
identifiable by someone who's actually
00:07:07
having diabetes so that's not normal
00:07:09
that glucose in the air because a
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hundred percent of that should be
00:07:12
actually being reabsorbed and the reason
00:07:15
why is we have these transporters here
00:07:17
that are designed to be able to bring in
00:07:18
the sodium and the glucose and they can
00:07:20
bring that up until the blood levels
00:07:21
usually the actual glucose levels in the
00:07:23
bloodstream go above 180 milligrams per
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deal then the transporters are getting
00:07:27
saturated and you reach was called a
00:07:30
transport maximum and then it starts
00:07:31
getting lost in the urine okay so we
00:07:34
talked about that what other things were
00:07:36
being reabsorbed here not just urea and
00:07:38
all these different electrolytes we also
00:07:39
said that small proteins were being
00:07:41
absorbed here too so small molecular
00:07:44
weight proteins small proteins like
00:07:46
insulin albumin we said even a little
00:07:49
bit of the hemoglobin these molecules
00:07:51
can actually get reabsorbed so small
00:07:52
proteins can actually get reabsorbed
00:07:55
into the bloodstream and we said it was
00:07:57
by an endo cytosis mechanism what else
00:07:59
did we say we also said that lipids
00:08:01
remember lipids they're really weird
00:08:03
lipids actually get reabsorbed in this
00:08:05
process too because what it's passed a
00:08:08
diffusion they can diffuse right to the
00:08:10
fossil of a bilayer so the lipids can
00:08:12
also get reabsorbed into the bloodstream
00:08:16
okay so we talked about lipids small
00:08:18
proteins all of these different
00:08:19
electrolytes and the organic nutrients
00:08:21
what else and then leave in this
00:08:22
metabolic waste urea what lots of things
00:08:25
that are being secreted how we define
00:08:26
tubular secretion it's the process of
00:08:28
moving things from the blood into the
00:08:30
actual filtrate how does that happen
00:08:32
well you know that we can actually
00:08:34
excrete certain drugs in this area so we
00:08:36
can actually take certain drugs I'm not
00:08:38
going to go over the many drugs that you
00:08:39
can actually excrete in this process but
00:08:42
one thing I do want you guys to know is
00:08:44
that in order for us to excrete drugs in
00:08:46
order for us to excrete protons
00:08:50
in order for us to excrete other
00:08:52
different types of metabolic waste
00:08:54
products so other different types of
00:08:55
metabolic waste products for example
00:08:57
limonium and even small trace amounts of
00:09:00
creatine are creatinine these substances
00:09:04
here in order for them to get pumped
00:09:06
over here it depends upon the presence
00:09:09
of ATP we need ATP in order for us to be
00:09:12
able to pump these substances from the
00:09:14
blood and into the actual filtrate so
00:09:17
all of these processes here require the
00:09:19
presence of ATP ok now that's one thing
00:09:27
and not only can you actually push these
00:09:29
protons out right depending upon what
00:09:31
the situation might be if you're in a
00:09:33
situation when you're in metabolic
00:09:34
acidosis you'll pump the protons out you
00:09:36
can also get rid of bicarb so there is
00:09:38
certain situations in which you can
00:09:40
actually lose by car but we'll talk
00:09:41
about that when you get over to the
00:09:42
intercalated B cells okay so for the
00:09:45
most part this covers in general what we
00:09:47
talked about in the proximal convoluted
00:09:48
tubule video then as we get down to the
00:09:52
loop of Henle what did we say actually
00:09:54
before we do that what was the
00:09:55
milliosmoles we got to make sure we
00:09:57
bring up that milliosmoles of right the
00:09:58
osmolality what do we say was the
00:10:00
general flow as we move our way down
00:10:02
okay we said as we move our way down
00:10:05
goes from about what it goes from 300
00:10:09
milliosmoles and it works its way down
00:10:11
work from that point let's see how that
00:10:14
goes okay so you guys remember it starts
00:10:17
up here at 300 milliosmoles and then it
00:10:19
works downwards to about 500 millivolts
00:10:21
then we get down to about maybe 700
00:10:24
millivolts then we get down to about 900
00:10:27
million moles and as we get really
00:10:29
really deep down into the renal medulla
00:10:30
you can hit 1200 milliosmoles now really
00:10:35
really briefly let me show you what i'm
00:10:37
talking about here in a side diagram
00:10:38
let's come over here for a second just a
00:10:41
real quick side diagram I draw a kidney
00:10:43
here so we're clear
00:10:46
let's say I take one piece here I take
00:10:48
one lobe here okay and here's the calyx
00:10:50
which is going to collect the actual
00:10:52
you're in at ripping off this is a renal
00:10:54
pyramid the renal pyramid is two parts
00:10:56
this part here is the cortex it's more
00:10:59
of like the lighter granulated tissue
00:11:01
and then the other part was the renal
00:11:03
medulla
00:11:03
and that was that nice little striated
00:11:05
part right now was dude a lot of the
00:11:06
kidney tubules now what we're trying to
00:11:09
say here with this renal you know
00:11:10
medullary gradient is that as you move
00:11:13
your way from the cortex which is where
00:11:14
the proximal convoluted tubule and the
00:11:17
distal convoluted tubule and even the
00:11:20
glomerular capillary we moved down 300
00:11:22
500 700 900 12 under that's what we're
00:11:26
saying
00:11:27
so the actual osmolality or the
00:11:29
medullary grading and increasing as you
00:11:31
go down that's what we're trying to say
00:11:34
okay so now that we got that let's come
00:11:36
back over here for a second okay so what
00:11:38
do we say was the plasma osmolality of
00:11:40
the actual blood the blood plasma we
00:11:43
said it was approximately around 300
00:11:46
milliosmoles and then we said due to the
00:11:48
filtration process as it's moving across
00:11:50
we said it should be equal so isotonic
00:11:53
right so this actual should be 300
00:11:56
milliosmoles in the proximal convoluted
00:11:58
tubules
00:11:59
these should equalize so they should be
00:12:00
isotonic with one another then we said
00:12:03
after all the reabsorption and secretion
00:12:04
mechanisms when it comes out here into
00:12:06
this descending limb it should be what
00:12:09
300 milliosmoles let's do this in a
00:12:11
different color make it bright so that
00:12:13
you guys remember so with this color
00:12:15
here one more let's do with orange let's
00:12:18
make this 300 milliosmoles so whenever
00:12:23
it's leaving when it's leaving the
00:12:25
proximal convoluted tubule it's 300
00:12:27
milliosmoles okay sweet let's get back
00:12:29
to this as we go up the ascending limb
00:12:32
of the loop of Henle what do we say we
00:12:34
had there remember we were pumping in
00:12:36
from the filtrate we were pumping out
00:12:38
sodium we were pumping out potassium and
00:12:41
we were pumping out the two chloride
00:12:43
ions right through the sodium potassium
00:12:44
to cloud co-transporter and this was
00:12:48
happening along the entire length of the
00:12:50
ascending limb and it was doing a lot of
00:12:53
this right how much of this sodium this
00:12:58
potassium and this chloride is actually
00:13:00
getting pumped out well a decent amount
00:13:02
not as much as in the proximal
00:13:04
convoluted tubule but it's still a
00:13:06
decent amount
00:13:06
remember we said about 65% of the sodium
00:13:10
here and it's about 25% of the sodium
00:13:13
within the ascending limb
00:13:16
for the potassium it honestly it ranges
00:13:19
so generally they say it's approximately
00:13:21
about 30% and then for the chloride ions
00:13:27
this is about 30%
00:13:29
okay so again sodium 25 percent
00:13:33
potassium 30 and chloride about 30
00:13:35
percent we're at the calcium and
00:13:37
magnesium remember we were actually
00:13:39
having what was happening remember some
00:13:41
of those potassium ions with my green
00:13:42
mark raise some of the potassium and
00:13:44
some of the potassium lines were leaking
00:13:45
back in because there's a different
00:13:48
gradients right and then when the
00:13:50
potassium was leaking back into this
00:13:51
actual tube you'll lumen it was
00:13:53
generating a nice positively charged
00:13:57
membrane depolarization right and what
00:14:00
did that do it caused some of those
00:14:02
calcium lines that was in this area to
00:14:03
leak out remember there was calcium and
00:14:06
there was magnesium and these ions
00:14:10
started leaking out by that passive para
00:14:12
cellular transport right out into the
00:14:14
actual medullary space and they were
00:14:17
also contributing to the medullary
00:14:19
interstitial gradient making it saltier
00:14:21
as you go down so what do we say we said
00:14:24
if we had a lot of sodium a lot of
00:14:26
potassium a lot of chloride a lot of
00:14:31
magnesium and a lot of calcium that was
00:14:36
making the medulla really salty and then
00:14:38
what do we say we said here that water's
00:14:41
coming down he's like a lot of saltiness
00:14:43
over there I gotta go so what happens a
00:14:45
lot of the water starts leaking out
00:14:48
through the aquaporin ones into the
00:14:51
medullary interstitial space to where
00:14:53
there's actual all these solutes
00:14:55
particularly sodium and chloride right
00:14:57
now when that happens what a lot of this
00:14:59
water is leaking out due to the sodium
00:15:03
in the potassium and chloride and
00:15:04
calcium and magnesium
00:15:05
getting pumped out as it's going up what
00:15:08
do we call that we called that D
00:15:13
counter-current multiplier
00:15:19
mechanism right okay sweet deal so that
00:15:25
was where a lot of the water is getting
00:15:26
reabsorbed so a lot of the water is
00:15:27
getting reabsorbed right here too so we
00:15:29
said sixty-five percent there it's
00:15:31
approximately about 25 percent here okay
00:15:34
because right with 65 plus 25 55 plus 25
00:15:37
is zero Terry that one right there yeah
00:15:39
so we're good yeah sorry so again about
00:15:42
25 percent of the water is reabsorbed
00:15:46
right here reason why I did that because
00:15:48
there should only be about 10 percent
00:15:50
left whenever we get up to the actual
00:15:52
specifically the distal convoluted
00:15:54
tubule okay okay 25 percent of the water
00:15:58
we got all that part there now as we
00:16:01
take this guy up okay as we take this
00:16:05
guy up we're going to bring this
00:16:06
actually should just not be 25 percent
00:16:08
this should actually be 15 percent I'm
00:16:10
sorry let me fix that this should be 20
00:16:12
percent water left over okay so as we
00:16:15
bring this actual filtrate up what do we
00:16:19
say okay we're going to look at the
00:16:22
actual tonicity for this in order for us
00:16:24
to understand this we've lost a lot of
00:16:27
water as we lost a lot of water out of
00:16:29
the descending limb what are we losing
00:16:31
then remember that the concept of
00:16:33
tonicity we said there was hypertonic
00:16:35
and then we said that there was isotonic
00:16:38
and then we said that there was
00:16:41
hypotonic hyper means that there's more
00:16:45
solute less water
00:16:47
isotonic means that there's a just an
00:16:48
equal amount of water and solutes
00:16:50
hypotonic means that there's actually a
00:16:52
lot of water and left solute when we
00:16:54
lost a lot of water if we lost a lot of
00:16:56
ones that means that this is actually
00:16:57
going to be hypertonic as compared to
00:17:00
the plasma osmolality so right here
00:17:02
should be hypertonic okay Queen so hyper
00:17:06
sonic right there as we make the turn
00:17:10
and we go up then when we do we're
00:17:11
pumping out a lot of salt potassium
00:17:13
chloride calcium magnesium and there's
00:17:16
still about 20% of water left over if
00:17:18
that's the case then as all this process
00:17:22
is occurring throughout the entire
00:17:23
length of the ascending limb by the time
00:17:25
we go into the distal convoluted tubules
00:17:26
what should it be it should be about 100
00:17:31
to 200
00:17:33
milliosmoles so this is very hypotonic
00:17:38
right a lot of water very little salty
00:17:41
it's not very salty and this is why
00:17:43
that's why may that little mistake sorry
00:17:45
20 percent of it should actually be
00:17:47
water and then a little bit of about 10
00:17:49
percent of it should actually be sodium
00:17:51
okay all right cool so hypertonic as you
00:17:56
get done with this one there should be
00:17:57
hypotonic then as we went into the
00:18:01
distal convoluted tubules so there was
00:18:02
two parts the early distal tubules and
00:18:04
the late distal tubules so you guys
00:18:05
remember we kind of separated those kind
00:18:08
of like right here right and what did we
00:18:11
say happened we said with alien early
00:18:14
distal two of you oh we had those sodium
00:18:15
and chloride symporters right we were
00:18:18
bringing the sodium in we were also
00:18:19
bringing the chloride in and we were
00:18:21
doing it through these actual nice
00:18:22
protein channels but the only way that
00:18:25
we could really do this was on the
00:18:26
basolateral membrane what do we have we
00:18:30
had those sodium potassium pumps which
00:18:32
were comping the sodium right against
00:18:35
its concentration gradient and the
00:18:36
potassium against its concentration
00:18:38
gradient approximately 3 sodium for
00:18:40
every 2 potassium and what do we say
00:18:42
this process required they required a
00:18:44
lot of energy so required ATP but it
00:18:47
helped to be able to do what it helped
00:18:50
to be able to bring the sodium and the
00:18:51
chloride in and then what could happen
00:18:53
with these guys we said that the sodium
00:18:55
could actually be brought out into the
00:18:57
blood and the court could be brought
00:18:58
onto the blood right and this is the
00:19:00
process of reabsorption ok what else do
00:19:04
we say could happen here we also said
00:19:06
that at the other early part of the
00:19:08
distal to build their specialized
00:19:10
specificity depending upon hormones
00:19:12
right remember there was that hormone
00:19:14
that we talked about produced by a gland
00:19:17
let's actually show them up here
00:19:18
remember we had here the thyroid gland
00:19:22
and then on the back of the thyroid
00:19:24
gland you had these tiny little glands
00:19:25
here they were called the parathyroid
00:19:27
gland and they were producing a special
00:19:29
hormone and that special hormone was
00:19:31
called the parathyroid hormone and what
00:19:35
was the parathyroid hormone responding
00:19:36
to it was responding to low blood
00:19:38
calcium levels hypocalcemia so whenever
00:19:41
there is hypo kalsi Nia
00:19:45
this can be a stimulus to the
00:19:47
parathyroid gland and cause the
00:19:49
parathyroid hormone to produce to be
00:19:51
produced and again what does
00:19:52
hypocalcemia low blood calcium levels
00:19:56
when the parathyroid hormone comes over
00:19:58
here what did he do
00:19:59
remember he stimulated a g-protein
00:20:02
coupled receptor and the overall result
00:20:04
was the activated cyclic AMP II we're
00:20:07
not going to go through the whole
00:20:07
mechanism here but remember he activated
00:20:10
cyclic AMP II which activated protein
00:20:11
kinase a and what did that do that
00:20:15
activated a specialized channel and this
00:20:19
channel is not as a modulated channel
00:20:21
right it's dependent upon parathyroid
00:20:23
hormone so a protein kinase a does is he
00:20:25
comes over here and phosphorylates that
00:20:27
channel and what happens it allows for
00:20:30
calcium ions that are still in the
00:20:32
filtrate right because about 10 percent
00:20:34
of the calcium is actually going to be
00:20:35
coming about to this point here the
00:20:37
calcium can get reabsorbed here but a
00:20:39
defense upon that phosphorylation point
00:20:41
and then what else did we say we also
00:20:43
say that there were these transporters
00:20:45
on the basolateral membrane that were
00:20:47
pumping sodium in while you pump the
00:20:50
calcium out into the blood to get the
00:20:54
calcium out here it's a blood stream to
00:20:56
increase the blood calcium levels and it
00:20:58
could be by this sodium calcium
00:20:59
exchanger or it could also be due to
00:21:01
another exchanger which is actually
00:21:05
going to be let's put that one right
00:21:06
here this could be due to protons
00:21:09
protons would have to come in and then
00:21:12
this calcium ions would have to come out
00:21:15
and this would actually depend upon the
00:21:17
direct utilization of ATP alright so
00:21:20
this process right here would require
00:21:21
ATP so we deal okay that was talking
00:21:27
about the calcium reabsorption but again
00:21:28
we said it was dependent upon
00:21:29
parathyroid hormone you know what else
00:21:31
is really cool about the parathyroid
00:21:32
hormone that he's not only causing this
00:21:34
calcium reabsorption he also deals with
00:21:36
phosphates in the blood so you know in
00:21:38
certain situations force phosphate
00:21:39
actually reabsorbed come here for a
00:21:41
second phosphate is actually reabsorbed
00:21:43
right here let's you draw a phosphate
00:21:46
and a let's do this one and actually
00:21:49
just do this one black so here's the
00:21:52
phosphate right
00:21:53
so you have and usually it's in the form
00:21:55
of hpo4 to negative right
00:21:58
mono hydrogen fall
00:21:59
State and what happens is this phosphate
00:22:01
can actually naturally get reabsorbed
00:22:03
into the bloodstream actually a good
00:22:05
portion of about eighty-five percent of
00:22:07
it is actually absorbed within the
00:22:08
proximal convoluted tubules
00:22:10
but if the parathyroid hormone is
00:22:13
present if the parathyroid hormones
00:22:16
present what it will actually do is is
00:22:18
it'll actually cause phosphate excretion
00:22:20
so what the parathyroid hormone will
00:22:23
come over here and do is it will inhibit
00:22:25
this process if it inhibits this process
00:22:27
the phosphate is lost in the air and
00:22:29
that cool yeah all right
00:22:31
let's come back over here for a second
00:22:34
another thing that I want to talk about
00:22:37
here is right here this was this
00:22:39
structure here remember we call this the
00:22:40
basal recta we also had another special
00:22:43
name for it he was also called the
00:22:47
counter-current exchanger right he
00:22:52
wasn't responsible for making the
00:22:54
medullary interstitial gradient this
00:22:55
whole nice saltiness of the medulla he
00:22:58
helped to maintain it right to prevent
00:23:00
the rapid removal of the sodium chloride
00:23:02
how did he do that
00:23:03
remember we said some of that salt that
00:23:05
sodium was pumped out here that
00:23:07
potassium was pumped out here the two
00:23:09
chloride ions were pumped out here what
00:23:11
happens is as you move down well again
00:23:13
what's that magic a inter social
00:23:14
gradient like 300 500 700 900 1200 about
00:23:20
right this is in milliosmoles as you go
00:23:23
down and get saltier
00:23:24
so what likes to happen then as you go
00:23:27
down if you think about it if it's
00:23:30
really really salty who's going to want
00:23:31
to leave
00:23:32
water water loves this salty stuff so as
00:23:35
you're coming down water is actually
00:23:37
going to start leaking out into this
00:23:40
actual imaginary interstitial space okay
00:23:45
and then salt is going to be really
00:23:46
really rich in this area so it's going
00:23:48
to actually move in so what will happen
00:23:50
to this actual salt the sodium and the
00:23:53
chloride ions will move in and as you
00:23:57
think about that as you're going down is
00:23:59
trying to equilibria with the actual
00:24:01
medullary interstitial gradient so for
00:24:02
example B 300 here 500 in here 700 in
00:24:06
here 900 here and 1200 here but then
00:24:08
when it makes the turn over here
00:24:10
something really cool happens
00:24:11
the exact opposite occurs now the water
00:24:14
is going to want to come back in as the
00:24:18
water starts coming back in a little bit
00:24:21
of salt is actually thrown back out but
00:24:25
here's what's really cool as the salt
00:24:28
its thrown back out into the medulla to
00:24:32
prevent the rapid removal he keeps a
00:24:36
little bit of that salt a little bit you
00:24:39
wouldn't know how much okay what was it
00:24:41
going in it should be 300 milliosmoles
00:24:43
that's what we said the plasma
00:24:44
osmolality is leaving it's just a little
00:24:47
bit higher 325 million Wells so he helps
00:24:51
to contribute to the rapid removal of
00:24:53
the sodium and chloride from this
00:24:55
medullary inter station to help to
00:24:57
contribute and maintain the medullary
00:25:00
interstitial gradient okay sweet deal
00:25:03
that was there with the counter current
00:25:05
exchanger then we got into the late
00:25:08
distal tubules and that one we also said
00:25:10
was actually very dependent upon a
00:25:11
hormone what was that hormone that
00:25:13
hormone was actually going to be
00:25:15
aldosterone right and we said
00:25:18
aldosterone was actually produced by
00:25:20
what was produced by the adrenal cortex
00:25:22
and we said there was a special part of
00:25:24
the adrenal cortex here right it was
00:25:26
called the zona glomerulosa and we said
00:25:29
the zona glomerulosa is producing
00:25:32
aldosterone and aldosterone is usually
00:25:34
stimulated whenever there's presence of
00:25:36
angiotensin 2 or if the sodium levels in
00:25:39
the blood are low remember we said the
00:25:41
sodium levels in the blood are low in
00:25:44
the potassium levels in the blood are
00:25:45
high that could stimulate the release of
00:25:47
aldosterone as well as angiotensin 2 is
00:25:51
a stimulator of this ok and this is a
00:25:53
stimulator okay da strands released what
00:25:57
does he do
00:25:58
we're not going to go over the whole
00:25:59
mechanism we already did that we're
00:26:02
going to say that he just stimulates
00:26:03
special genes right and those genes lead
00:26:06
to the production of 3 different
00:26:07
proteins one of the proteins was to get
00:26:11
what get the sodium in then we said it
00:26:16
developed another protein and this other
00:26:17
protein that it made was designed to be
00:26:19
able to pump 3 sodium out into potassium
00:26:22
in so he's increasing the expression of
00:26:24
the sodium potassium
00:26:25
pumps right and these pumps required ATP
00:26:29
because they're pumping things against
00:26:31
their concentration gradient what else
00:26:33
do we say it also made these channels
00:26:37
for the potassium to excrete the
00:26:40
potassium out right so this potassium
00:26:42
though is really high in the blood it's
00:26:43
actually getting pumped out into the
00:26:46
filtrate and the sodium that was really
00:26:48
low in the bloodstream we're increasing
00:26:50
it by bringing more sodium into the
00:26:54
bloodstream okay so we're trying to
00:26:55
bring in the sodium up and put the
00:26:56
potassium down what a wise angiotensin
00:27:00
to being stimulated because we have low
00:27:01
blood pressure so there might not be
00:27:03
enough of water in the bloodstream if we
00:27:04
bring more water in we can increase the
00:27:06
blood volume and increase the blood
00:27:07
pressure how does that happen
00:27:08
remember there's another structure here
00:27:11
let's draw this structure and about
00:27:17
mammillary bodies hypothalamus anterior
00:27:20
and posterior pituitary they're not
00:27:22
testicles I promise we said that there's
00:27:24
these specialized Osmo receptors that
00:27:27
are stimulated right usually do the
00:27:29
called organum vascular some of lamina
00:27:31
terminalis a sub funicular organ they
00:27:33
stimulate the Supra optic nucleus and
00:27:36
trigger the release of and - Doretta
00:27:38
core Mon whenever the plasma osmolality
00:27:41
is what whenever you have a high plasma
00:27:45
osmolality what does that mean molality
00:27:50
I'm allowing means whenever you have a
00:27:52
high plasma osmolality that means that
00:27:54
you have a lot of salt and very little
00:27:56
water so what we're going to do we're
00:27:58
going to release antidiuretic hormone
00:27:59
answered erratic comas gonna work on the
00:28:01
collecting duct the deeper parts of it
00:28:02
and the cortical part here or like the
00:28:04
late distal tubules so look what happens
00:28:06
inside a'right a corpsman can come over
00:28:08
here and it can stimulate this cell to
00:28:10
do what to make special aquaporins like
00:28:13
aquaporin - so if we make these
00:28:16
aquaporin two molecules what is that
00:28:17
going to do that's going to open up
00:28:19
these channels right they're going to
00:28:21
make these channels that can pull water
00:28:23
with it and if the water is flowing in
00:28:26
what's going to happen the water can
00:28:27
actually go into the bloodstream and if
00:28:30
the water goes into the bloodstream what
00:28:31
happens to the actual blood volume
00:28:34
increases the blood volume which does
00:28:35
what to the blood pressure increases the
00:28:38
blood
00:28:38
all right we deal there right so again
00:28:42
now doctrine does what three things
00:28:44
increases the sodium-potassium pumps
00:28:47
makes the sodium channels to bring
00:28:48
sodium in and makes these actual
00:28:50
potassium channels to put potassium out
00:28:52
and then the presence of antidiuretic
00:28:54
hormone it can express aquaporin tubes
00:28:56
which can bring the actual water and
00:28:59
increase blood volume increase blood
00:29:00
pressure all right in the same way anted
00:29:03
Rhetta Cuomo can act on the cells or the
00:29:05
collecting duct look how he does it here
00:29:06
remember which actually showed you that
00:29:08
antidiuretic hormone we comes over here
00:29:11
and binds on to v2 receptors and
00:29:15
remember these v2 receptors of the basal
00:29:17
press and receptors activated a
00:29:19
g-protein activated adenylate cyclase
00:29:23
which did what turned ATP into cyclic
00:29:27
A&P and the cyclic AMP e activated
00:29:29
protein kinase a you guys already know
00:29:32
this what happens it increases the
00:29:35
expression I'm sorry not the expression
00:29:37
it actually activates by phosphorylating
00:29:40
these specialized proteins on these
00:29:45
vesicles right remember it activates
00:29:47
these specific proteins on the vesicles
00:29:50
let's show you these proteins here in
00:29:52
red I say here is these proteins on the
00:29:54
synaptic vesicles and what does protein
00:29:57
kinase a do protein kinase a comes over
00:30:00
here and actually phosphorylates them
00:30:02
and stimulates them to migrate to the
00:30:05
membrane and what happens it plugs into
00:30:08
the membrane these little aquaporins and
00:30:13
again this is aquaporin too and then
00:30:17
what starts coming in water and if water
00:30:20
starts flowing in what's going to happen
00:30:24
the water will flow into the actual
00:30:27
tubular cells and then there's these
00:30:28
aquaporin 3 & 4 proteins we said on the
00:30:31
basolateral membrane what will happen
00:30:33
the water will go into the bloodstream
00:30:35
as the water goes into the bloodstream
00:30:37
what happens to the actual blood volume
00:30:39
you're going to increase in blood volume
00:30:41
which increases your blood pressure what
00:30:43
else did we say well originally the
00:30:45
plasma osmolality was high it was very
00:30:48
hypertonic if we bring more water in we
00:30:52
bring the
00:30:52
asthma osmolality down back to a normal
00:30:58
range of approximately 300 milliosmoles
00:31:02
okay what else did we say remember we
00:31:05
had the intercalated a thousand
00:31:06
intercalated b-cells and they were
00:31:08
functioning during metabolic acidosis
00:31:10
and alkalosis remember what they were
00:31:12
doing remember we had the a cell let's
00:31:14
say this is the intercalated a cell
00:31:15
remember was actually taking the co2
00:31:19
combining with water to form carbonic
00:31:21
acid right and then if you remember
00:31:24
carbonic acid which age was h2 co3 which
00:31:28
can disassociate into protons and
00:31:31
bicarbonate and we said remember
00:31:34
intercalated a cells us for acidosis so
00:31:37
what does that mean
00:31:37
we can pump proton out and who do we
00:31:41
bring in a little bit of potassium right
00:31:44
then what do we say if it's acidosis
00:31:47
that means that the blood pH is really
00:31:49
low what are going to do we're going to
00:31:51
bring bicarb into the blood and what are
00:31:54
we going to do to prevent excessive
00:31:55
changes in the ions moving across this
00:31:57
membrane we're going to bring chloride
00:31:58
ions in if we bring a lot of bicarb out
00:32:01
what you're going to do the pH it's
00:32:03
going to bring the pH back up to normal
00:32:04
ranges okay that was one of things we
00:32:06
said then what else remember we had the
00:32:09
intercalated B cell this was the be
00:32:12
filling it was four basic conditions our
00:32:14
metabolic alkalosis right same concept
00:32:17
what do we say here co2 combines with
00:32:20
water when that happens what do you get
00:32:23
you get carbonic acid this is driven by
00:32:26
the carbonic anhydrase enzyme and again
00:32:28
this is driven by the carbonic anhydrase
00:32:29
enzyme this breaks down into bicarbonate
00:32:33
and into protons what do we say is the
00:32:37
difference here now we excrete aathi
00:32:39
bicarb and we bring in the chloride ions
00:32:43
right to prevent the excessive change
00:32:44
there then what do we do we push the
00:32:47
protons out here why because we said
00:32:49
that the blood is in a basic situation
00:32:51
what does that mean that means that the
00:32:53
pH is high if we bring a lot of these
00:32:55
protons in what is it going to do it's
00:32:58
going to bring the pH back
00:33:01
okay and that's how our body deals with
00:33:03
this metabolic acidosis and alkalosis
00:33:05
situations what else did we say remember
00:33:08
we also said that there can also be a
00:33:10
little bit of certain substances that
00:33:12
can be secreted out in this area too I
00:33:13
draw one more cell here remember we said
00:33:16
we can actually have excretion of drugs
00:33:19
we can actually excrete out ammonia
00:33:21
remember we have ammonia and they can
00:33:24
combine with one of these protons out
00:33:25
here like for example this proton here
00:33:27
let's say it combines with this proton
00:33:29
that actually got pushed down what can
00:33:31
we get out of this these two react we
00:33:34
get ammonium and what else do we say
00:33:37
that we could excrete - it could also
00:33:39
excrete creatinine all right and there's
00:33:45
even other substances that could also be
00:33:46
treated like uric acid and even a little
00:33:48
bit of other nitrogenous waste products
00:33:50
one more thing at the end part of the
00:33:54
collecting duct what was that molecule
00:33:55
that actually was left over a lot of
00:33:57
water was lost so as a lot of water was
00:34:00
lost out to extend this actual
00:34:02
collecting duct down a little farther
00:34:04
here and we get down as we get on to the
00:34:08
bottom part there's just a little bit of
00:34:11
all of this substance left over what
00:34:14
color did we make him let's make him
00:34:15
green this substance is called urea
00:34:19
remember your Rio was absorbed within
00:34:21
the actual what the proximal convoluted
00:34:23
tubule well some of the urea is actually
00:34:27
reabsorbed here at the end of the
00:34:29
collecting duct and what do we say that
00:34:31
urea is doing we said some of that urea
00:34:33
is actually being recycled
00:34:36
remember it's actually moving over here
00:34:37
and as it's moving over here to get
00:34:40
recycled what happens some of that urea
00:34:42
might accumulate here in the medullary
00:34:46
interstitial space and urea is a solute
00:34:48
it's more of a lipid soluble solute but
00:34:51
still nonetheless it can attract water
00:34:53
because it can contribute to the
00:34:55
medullary interstitial gradient what is
00:34:58
that going to do that's going to allow
00:34:59
for more water to flow out of what more
00:35:02
water to flow out of the descending limb
00:35:04
so it's going to contribute to making
00:35:06
concentrated urine so again what does
00:35:08
this process here called it's called
00:35:11
urea
00:35:13
recycling all right sweet deal and again
00:35:18
a lot of that urea could actually get
00:35:19
lost in the urine as well as well as
00:35:21
other substances that we'll talk about
00:35:23
during the Victorian reflex when we talk
00:35:25
about the composition in the urine okay
00:35:27
so in a nutshell guys we covered a lot
00:35:31
of this stuff here right one thing I
00:35:33
didn't finish off with is this sodium in
00:35:36
water I'm sorry twenty percent of the
00:35:37
water right is remaining 20 percent of
00:35:40
water because 65 percent of it was
00:35:41
reabsorbed here and the PCT and about 15
00:35:44
percent of it was reabsorbed here in the
00:35:45
loop of Henle specifically the
00:35:47
descending the remaining water that's
00:35:51
left over is dependent upon the presence
00:35:53
of antibiotic hormones so you the amount
00:35:56
of water that you reabsorb is variable
00:35:58
the sodium there's about 10 percent of
00:36:02
the actual sodium remaining this sodium
00:36:05
a small percentage about five to six
00:36:09
percent of the sodium is actually to the
00:36:13
sodium chloride symporter the remaining
00:36:16
of four or five percent is dependent
00:36:19
upon the actual odd Ostrom okay
00:36:23
and then we said that calcium was
00:36:24
dependent upon the parathyroid hormone
00:36:26
iron is in this video we covered a lot
00:36:28
of information we covered basically
00:36:30
everything that we covered throughout
00:36:31
the series of videos I hope all of them
00:36:32
made sense I really hope you guys
00:36:33
enjoyed it if you did please hit the
00:36:35
like button comment down the comment
00:36:37
sections and subscribe

Tag

glomerulus
nephron
kidney function
aldosterone
ADH
proximal tubule
loop of Henle
urea recycling
electrolyte balance
renal system