Guyton and Hall Textbook of Medical Physiology Renal Regulation PDF

Summary

This chapter from Guyton and Hall's Textbook of Medical Physiology discusses renal regulation of electrolytes, specifically potassium, calcium, phosphate, and magnesium. It details the mechanisms for controlling blood volume and extracellular fluid volume, including factors like insulin and aldosterone, and the crucial role of the kidneys in maintaining electrolyte balance.

Full Transcript

CHAPTER 30

Renal Regulation of Potassium, Calcium, Phosphate,

UNIT V
and Magnesium; Integration of Renal Mechanisms for
Control of Blood Volume and Extracellular Fluid Volume

as a source of potassium during hypokalemia. Thus, redis-
REGULATION OF EXTRACELLULAR
tribution of potassium between the intracellular and
FLUID POTASSIUM CONCENTRATION
extracellular fluid compartments provides a first line of
AND POTASSIUM EXCRETION
defense against changes in extracellular fluid potassium
Extracellular fluid potassium concentration normally is concentration.
regulated at about 4.2 mEq/L, seldom rising or falling
more than ±0.3 mEq/L. This precise control is necessary
REGULATION OF INTERNAL
because many cell functions are sensitive to changes in
POTASSIUM DISTRIBUTION
extracellular fluid potassium concentration. For instance,
an increase in plasma potassium concentration of only 3 After ingestion of a normal meal, extracellular fluid potas-
to 4 mEq/L can cause cardiac arrhythmias, and higher sium concentration would rise to a lethal level if the
concentrations can lead to cardiac arrest or fibrillation. ingested potassium did not rapidly move into the cells.
A special difficulty in regulating extracellular potas- For example, absorption of 40 mEq of potassium (the
sium concentration is the fact that more than 98 percent amount contained in a meal rich in vegetables and fruit)
of the total body potassium is contained in the cells into an extracellular fluid volume of 14 liters would raise
and only 2 percent is contained in the extracellular fluid plasma potassium concentration by about 2.9 mEq/L if all
(Figure 30-1). For a 70-kilogram adult, who has about 28 the potassium remained in the extracellular compart-
liters of intracellular fluid (40 percent of body weight) and ment. Fortunately, most of the ingested potassium rapidly
14 liters of extracellular fluid (20 percent of body weight), moves into the cells until the kidneys can eliminate the
about 3920 mEq of potassium are inside the cells and excess. Table 30-1 summarizes some of the factors that
only about 59 mEq are in the extracellular fluid. Also, the can influence the distribution of potassium between the
potassium contained in a single meal may be as high as intracellular and extracellular compartments.
50 mEq, and the daily intake usually ranges between 50
and 200 mEq/day; therefore, failure to rapidly rid the Insulin Stimulates Potassium Uptake into Cells.
extracellular fluid of the ingested potassium could cause Insulin is important for increasing cell potassium uptake
life-threatening hyperkalemia (increased plasma potas- after a meal. In people who have insulin deficiency owing
sium concentration). Likewise, a small loss of potassium to diabetes mellitus, the rise in plasma potassium concen-
from the extracellular fluid could cause severe hypokale- tration after eating a meal is much greater than normal.
mia (low plasma potassium concentration) in the absence Injections of insulin, however, can help to correct the
of rapid and appropriate compensatory responses. hyperkalemia.
Maintenance of balance between intake and output of
potassium depends primarily on excretion by the kidneys Aldosterone Increases Potassium Uptake into Cells.
because the amount excreted in the feces is only about 5 Increased potassium intake also stimulates secretion of
to 10 percent of the potassium intake. Thus, the mainte- aldosterone, which increases cell potassium uptake. Excess
nance of normal potassium balance requires the kidneys aldosterone secretion (Conn’s syndrome) is almost invari-
to adjust their potassium excretion rapidly and precisely ably associated with hypokalemia, due in part to move-
in response to wide variations in intake, as is also true for ment of extracellular potassium into the cells. Conversely,
most other electrolytes. patients with deficient aldosterone production (Addison’s
Control of potassium distribution between the extra- disease) often have clinically significant hyperkalemia due
cellular and intracellular compartments also plays an to accumulation of potassium in the extracellular space,
important role in potassium homeostasis. Because more as well as renal retention of potassium.
than 98 percent of the total body potassium is contained
in the cells, they can serve as an overflow site for excess β-Adrenergic Stimulation Increases Cellular Uptake
extracellular fluid potassium during hyperkalemia or of Potassium. Increased secretion of catecholamines,

389
Unit V The Body Fluids and Kidneys

K+ intake Cell Lysis Causes Increased Extracellular Potassium
100 mEq/day Concentration. As cells are destroyed, the large amounts
of potassium contained in the cells are released into the
Extracellular Intracellular extracellular compartment. This release of potassium can
fluid K+ fluid K+
cause significant hyperkalemia if large amounts of tissue
4.2 mEq/L 140 mEq/L
are destroyed, as occurs with severe muscle injury or with
× 14 L × 28 L red blood cell lysis.

Strenuous Exercise Can Cause Hyperkalemia by
59 mEq 3920 mEq
Releasing Potassium from Skeletal Muscle. During
prolonged exercise, potassium is released from skeletal
K+ output
Urine 92 mEq/day
muscle into the extracellular fluid. Usually the hyperkale-
Feces 8 mEq/day mia is mild, but it may be clinically significant after heavy
100 mEq/day exercise, especially in patients treated with β-adrenergic
Figure 30-1. Normal potassium intake, distribution of potassium in blockers or in individuals with insulin deficiency. In rare
the body fluids, and potassium output from the body. instances, hyperkalemia after exercise may be severe
enough to cause cardiac toxicity.
Table 30-1 Factors That Can Alter Potassium
Distribution Between the Intracellular and Increased Extracellular Fluid Osmolarity Causes
Extracellular Fluid Redistribution of Potassium from the Cells to
Extracellular Fluid. Increased extracellular fluid osmo-
Factors That Shift K+ Factors That Shift K+ larity causes osmotic flow of water out of the cells. The
Into Cells (Decrease Out of Cells (Increase
Extracellular [K+]) Extracellular [K+])
cellular dehydration increases intracellular potassium
concentration, thereby promoting diffusion of potassium
Insulin Insulin deficiency (diabetes
mellitus) out of the cells and increasing extracellular fluid potas-
sium concentration. Decreased extracellular fluid osmo-
Aldosterone Aldosterone deficiency
(Addison’s disease) larity has the opposite effect.
β-adrenergic stimulation β-adrenergic blockade
Alkalosis Acidosis OVERVIEW OF RENAL POTASSIUM EXCRETION
Cell lysis Renal potassium excretion is determined by the sum
Strenuous exercise of three processes: (1) the rate of potassium filtration
Increased extracellular fluid (glomerular filtration rate [GFR] multiplied by the plasma
osmolarity potassium concentration), (2) the rate of potassium reab-
sorption by the tubules, and (3) the rate of potassium
secretion by the tubules. The normal rate of potassium
especially epinephrine, can cause movement of potas- filtration by the glomerular capillaries is about 756 mEq/
sium from the extracellular to the intracellular fluid, day (GFR, 180 L/day multiplied by plasma potassium
mainly by activation of β2-adrenergic receptors. Con­ concentration, 4.2 mEq/L). This rate of filtration is rela-
versely, treatment of hypertension with β-adrenergic tively constant in healthy persons because of the auto-
receptor blockers, such as propranolol, causes potassium regulatory mechanisms for GFR discussed previously and
to move out of the cells and creates a tendency toward the precision with which plasma potassium concentration
hyperkalemia. is regulated. Severe decreases in GFR in certain renal
diseases, however, can cause serious potassium accumu-
Acid-Base Abnormalities Can Cause Changes in lation and hyperkalemia.
Potassium Distribution. Metabolic acidosis increases Figure 30-2 summarizes the tubular handling of
extracellular potassium concentration, in part by causing potassium under normal conditions. About 65 percent of
loss of potassium from the cells, whereas metabolic alka- the filtered potassium is reabsorbed in the proximal
losis decreases extracellular fluid potassium concentra- tubule. Another 25 to 30 percent of the filtered potassium
tion. Although the mechanisms responsible for the effect is reabsorbed in the loop of Henle, especially in the thick
of hydrogen ion concentration on potassium internal dis- ascending part where potassium is actively co-transported
tribution are not completely understood, one effect of along with sodium and chloride. In both the proximal
increased hydrogen ion concentration is to reduce the tubule and the loop of Henle, a relatively constant fraction
activity of the sodium-potassium adenosine triphospha- of the filtered potassium load is reabsorbed. Changes in
tase (ATPase) pump. This reduction in turn decreases potassium reabsorption in these segments can influence
cellular uptake of potassium and raises extracellular potassium excretion, but most of the day-to-day variation
potassium concentration. of potassium excretion is not due to changes in

390
 Chapter 30 Renal Regulation of Potassium, Calcium, Phosphate, and Magnesium

65% 8% Renal Principal Tubular
(491 mEq/day) (60 mEq/day) interstitial cells lumen
756 mEq/day fluid
(180 L/day ×
4.2 mEq/L)
Na+
ENaC
Na+

UNIT V
Na+
27% ATP
(204 mEq/day) K+ K+ BK
K+

K+
ROMK

4% 0 mV –70 mV –50 mV
(30 mEq/day)
Figure 30-3. Mechanisms of potassium secretion and sodium reab­
sorption by the principal cells of the late distal and collecting tubules.
BK, “big” potassium channel; ENaC, epithelial sodium channel;
ROMK, renal outer medullary potassium channel.
12%
(92 mEq/day)
Figure 30-2. Renal tubular sites of potassium reabsorption and When potassium intake is low, secretion of potassium
secretion. Potassium is reabsorbed in the proximal tubule and in the in the distal and collecting tubules decreases, causing a
ascending loop of Henle, so only about 8 percent of the filtered load reduction in urinary potassium excretion. There is also
is delivered to the distal tubule. Secretion of potassium by the prin­ increased reabsorption of potassium by the intercalated
cipal cells of the late distal tubules and collecting ducts adds to the
cells in the distal segments of the nephron, and potassium
amount delivered, but there is some additional reabsorption by the
intercalated cells; therefore, the daily excretion is about 12 percent excretion can fall to less than 1 percent of the potassium
of the potassium filtered at the glomerular capillaries. The percent­ in the glomerular filtrate (to