Nephron

The functional unit of the kidney is the nephron. Approximately 1,250,000 of these units are present in each kidney. The shape of the nephron is unique, unmistakable, and admirably suited for its function. Each area of the nephron is selective with regard to its performance. Nephrons hold the filtrate that has been filtered from the blood. End products of metabolism are excreted, and metabolically important substances such as water are reabsorbed as needed.

The nephron (Figure 29-3) begins in the cortex at the glomerulus and ends where the tubule joins the collecting duct at the papilla. The glomerulus is a tuft of capillaries derived from the afferent arteriole. Blood is brought to the glomerulus by the afferent arteriole; blood that is not filtered returns to the circulation by way of the efferent arteriole (see Figure 29-3). The filtrate from the glomeruli enters the Bowman capsule, or capsula glomeruli, flows through a tortuous tube, or proximal convoluted tubule, and then goes to the loop of Henle, distal convoluted tubule, and collecting duct.

The nephron, which changes in shape and direction as it follows its course, is contained partly in the renal cortex and partly in the medulla (Figure 29-4). The cortex contains the Bowman capsule, glomerulus, and proximal and distal tubules. The thin, descending loop of Henle comes from the proximal tubule and extends toward the pyramid. The descending loop of Henle eventually bends on itself and forms an enlarged, ascending loop of Henle. The ascending limb joins the distal convoluted tubule.¹

The kidneys have two kinds of nephrons: cortical nephrons, which extend only partially into the medulla, and juxtamedullary nephrons, which lie deep in the cortex and extend deep into the medulla. One fifth to one third of the nephrons are juxtamedullary and play an important role in concentration of urine.

Renal Blood Supply

To understand how the kidneys function, it is essential to understand their blood supply. The kidneys are highly vascular. Although they represent only 0.5% of body weight, they receive 1100 to 1200 mL of blood per minute, or 20% to 25% of the cardiac output. Blood reaches these organs through the renal arteries. At the hilus of the kidney, the renal artery divides into several lobar arteries and then subdivides again into interlobar arteries, which run between the pyramids. When these vessels reach the corticomedullary zone, they make well-defined arches over the bases of the pyramids. These vessels, known as arcuate arteries, divide into a series of arteries known as interlobular arteries (see Figure 29-2). An interlobular artery may terminate as an afferent arteriole or as a nutrient artery to the tubule.

The afferent arterioles form the high-pressure capillary bed within the Bowman capsule called the glomerulus. Because little or no oxygen is removed in the glomerulus, the blood that is not filtered begins its passage to the venous system via the efferent arteriole. The efferent arteriole is smaller than the afferent arteriole, thereby affording some resistance to blood flow. The efferent vessel soon becomes a plexus of capillaries again, and this low-pressure bed is known as the peritubular capillary. The peritubular capillary bed winds and twists around the proximal and distal tubule. A few hairpin loops, called vasa recta, dip down among the loops of Henle. Anatomic arrangements of these capillary beds and the renal tubules set the stage for filtration, reabsorption, and concentration of urine.

After leaving the peritubular capillary, blood returns to the central circulation via the veins. Renal veins are named in reverse order of the arteries, and therefore are the interlobular, arcuate, interlobar, lobar, and renal veins. The renal vein leaves the kidney at the hilus and empties into the inferior vena cava.

The portion of the cardiac output that passes through the kidney is called the renal fraction. Because cardiac output in a 70-kg man is approximately 5600 mL/min, and blood flow through both kidneys is 1200 mL/min, the normal renal fraction is 21%. This flow may vary from 12% to 30%. Distribution of renal blood flow is to the renal cortex and the medulla, with the cortex receiving the larger amount. Values obtained from dogs indicate that 3 to 5 mL/g/min are distributed to the cortex, 1 to 2 mL/g/min to the outer medulla, and 0.3 to 0.6 mL/g/min to the inner medulla. Only a small portion of blood (1% to 2%) flows through the vasa recta in the medulla. ¹

Filtration

Filtration, which results from pressures that force fluids and solutes through the glomerulus, is the first step in the formation of urine. The quantity of glomerular filtrate formed each minute in all nephrons is called the glomerular filtration rate (GFR). The filtration fraction is the quantity of renal plasma flow that becomes filtrate and is defined as GFR divided by the flow to one kidney. Because the GFR is approximately 125 mL/min, and the flow to one kidney is 650 mL/min, the filtration fraction is 125/650, or 19% (approximately one fifth) of plasma flow. Of the 125 mL/min (or 180 L/day) of this protein-free filtrate made, 99% is reabsorbed from the renal tubules, and the remaining small portion is excreted as urine.¹

Tubular Reabsorption and Secretion

Conversion of glomerular filtrate to urine is the result of filtration at the glomerulus, tubular reabsorption or transport from the tubular lumen to the renal cell, and secretion or transport from the renal cell to the filtrate. Of all that is filtered or secreted, 99% is reabsorbed as the filtrate moves along the nephron.

Tubular reabsorption permits conservation of essential substances such as water, glucose, amino acids, and electrolytes. Some substances, such as water and sodium, are reabsorbed throughout the nephron, whereas others, such as glucose, are completely reabsorbed when plasma concentrations are low. Certain substances have a reabsorption maximum value, and after that value is reached, excess filtered material is excreted, regardless of plasma concentration. This maximum value is termed maximum transport. Maximum transport occurs because of saturation of a carrier for a particular substance.

By the time the blood has reached the peritubular capillary, one fifth of the plasma has been filtered into the Bowman capsule. The hydrostatic pressure in this low-pressure capillary bed has dropped to 13 mmHg, whereas the osmotic pressure has increased to 30 to 32 mmHg. The peritubular capillaries are extremely porous compared with those in other body tissues, and their proximity to the proximal and distal tubule sets the stage for movement of water and solutes from the tubule to the peritubular capillary bed. Anatomic location and the colloid osmotic pressure of plasma proteins account for the rapid absorption required in this area.¹

Renal Hormones

Renal Regulation of Acid-Base Balance

The kidneys, along with the body’s fluid buffers and respiratory system, play a major role in regulating acid-base balance. Epithelial cells of the proximal tubules, the thick portion of the loop of Henle, distal tubules, and collecting ducts secrete hydrogen into the tubular fluid. This secretory process actually begins with CO₂ in the epithelial cells, where under the influence of carbonic anhydrase, CO₂ combines with water to form carbonic acid (H₂CO₃). H₂CO₃ dissociates into HCO₃ and hydrogen ions, and hydrogen ions are actively secreted into tubular fluid in exchange for sodium ions. This exchange maintains appropriate electrical balance between anions and cations in the tubular fluid.

An increase in HCO₃ in alkalosis means that the filtered amount of HCO₃ exceeds the amount of hydrogen secreted. Because excess HCO₃ must react with hydrogen (HCO₃⁻ + H⁺ → H₂CO₃ → CO₂⁻ + H₂O) and be absorbed as CO₂, excess HCO₃ ions are lost in the urine along with sodium. In this way, sodium and excess HCO₃ are removed from the extracellular fluid.

In acidosis the concentration of hydrogen ions increases to a level far greater than that of HCO₃ in the tubules. Excess hydrogen ions are lost in the urine through the phosphate or ammonia (NH₃) buffer system.

The phosphate buffer is composed of hydrogen phosphate (HPO₂⁻) and dihydrogen phosphate (H₂PO₄). Both of these ions become concentrated in the tubular fluid because of poor reabsorption. The quantity of HPO₂⁻ is normally fourfold that of H₂PO₄. Excess hydrogen ions entering the tubules combine with monohydrogen phosphate to form H₂PO₄, which is lost in the urine. A sodium ion is absorbed into the extracellular fluid in exchange for hydrogen. It combines with HCO₃, which was formed in the process of secretion of the hydrogen, and sodium bicarbonate is added to the extracellular fluid.

NH₃, which is synthesized by all epithelial cells except those in the thin segment of the loop of Henle, is also secreted into the tubules. NH₃ reacts with hydrogen to form the ammonium ion (NH₄). Ammonium ions are lost in the urine with chloride and other tubular anions.

The kidneys control extracellular fluid hydrogen concentration by excreting an acidic or basic urine. Excretion of acidic urine removes excess acid from the extracellular fluid, whereas loss of basic urine removes base from the extracellular fluid.

Concentration and Dilution of Urine

The kidneys have the ability to respond to the changing tonicity of body fluids by excreting dilute or concentrated urine. This function involves a countercurrent exchange system in which a concentration gradient causes fluid to be exchanged across parallel pathways (see Figure 29-6). In a countercurrent exchanger, reversal of flow in one stream results in the formation of a gradient that allows water and solutes to be exchanged along the length of the tube. The countercurrent exchanger in the kidney is the descending and ascending loop of Henle. The concentration gradient increases from the cortex to the tip of the medulla. The anatomic arrangement of this part of the nephron and sluggish blood flow in the vasa recta help maintain the gradient.

Plasma water filtered at the glomerulus is isotonic with plasma. The daily urinary output is approximately 1.5 L/day, and its osmolarity may vary from 40 to 1400 mOsm/L, depending on water intake or loss. This is possible because of the countercurrent mechanism.

Approximately two thirds of the tubular fluid is reabsorbed between the glomerulus and the end of the proximal tubule. The tonicity of the filtrate in this area is the same as that of the surrounding tissue, or 300 mOsm. As the filtrate leaves the proximal tubule, it passes through an increasingly more concentrated medulla. Changes in the thick ascending limb of the loop of Henle are responsible for the hypertonicity.

The thick ascending limb of the loop of Henle is responsible for the active transport of sodium and chloride into the medullary interstitium. In contrast to the descending limb of the loop of Henle, the tonicity of which is in equilibrium with that of the interstitium, the ascending loop has a low permeability to water. The active transport of sodium and chloride produces a gradient between the ascending loop of Henle on one side and the descending loop and interstitium of the renal medulla on the other. The descending limb is highly permeable to water but does not actively transport sodium and chloride. The hyperosmotic interstitium causes water to move out of the descending limb, and the filtrate in the descending tubule is concentrated to 1200 mOsm at the tip of the medulla. As the tubular fluid rounds the loop and enters the ascending limb, active transport of sodium and chloride and retention of water create a hypoosmotic fluid of 100 mOsm at the distal tubule.

The hypoosmotic fluid of the distal tubule is delivered to the collecting duct, where the final adjustments of urine volume and concentration take place. In the absence of ADH, water permeability is low, and water is not reabsorbed. Because sodium and chloride can be reabsorbed, the osmolality decreases to below that of the distal tubule, and the urine is dilute. When the need for water conservation arises, ADH is secreted, permeability of the collecting duct increases, and water diffuses out of the duct into the hyperosmolar environment of the medullary extracellular fluid. In this way urine is concentrated and its volume is reduced.

The sluggish blood supply of the vasa recta in the medulla allows blood to flow through the medullary tissue without disturbing the osmotic gradient. If blood flow were rapid, the medullary concentration gradient and the ability to concentrate the urine would be lost.1,5

Anesthetic Effects

General anesthesia is associated with a temporary depression of renal blood flow, GFR, urinary flow, and electrolyte excretion. Although similar changes occur after spinal and epidural anesthesia, the magnitude of change tends to parallel the degree of sympathetic block and blood pressure depression. This consistent and generalized depression of renal function has been attributed to a number of factors, including type and duration of surgical procedure, physical status of the patient, volume and electrolyte status, depth of anesthesia, and choice of agent.⁵

Anesthesia may alter renal function by direct or indirect effects. Indirect effects are mediated through changes in the circulatory, endocrine, or sympathetic nervous system. Anesthetic drugs alter the circulatory system by decreasing renal perfusion, increasing renal vascular resistance, or a combination of both. Drugs associated with catecholamine lead to vasoconstriction, an increase in renal vascular resistance, a decrease in renal blood flow, and a decrease in renal function. Volatile agents such as isoflurane cause a mild to moderate increase in renal vascular resistance as a compensatory response to decreased perfusion pressure secondary to alterations in cardiac output or systemic vascular resistance.6–10 Desflurane has been shown to produce hemodynamic effects comparable to those produced by isoflurane.¹¹ It increases heart rate and decreases both mean arterial pressure and systemic vascular resistance while maintaining cardiac output. In some studies, but not all, desflurane maintains arterial pressure and systemic vascular resistance to a greater degree than equianesthetic concentrations of isoflurane. Otherwise, desflurane and isoflurane have similar effects on most vascular beds, including the renal circulation.

Although earlier studies suggested that renal blood flow was reduced with sevoflurane, no renal functional or morphologic defects were noted after administration of this agent. Issues regarding the renal effects of the release of free fluoride ion associated with sevoflurane metabolism have been debated. Historically, high fluoride ion concentrations in the range of 60 to 90 µmol/L after methoxyflurane metabolism have led to nephrotoxicity characterized by polyuria. This methoxyflurane polyuria was commonly referred to as high-output renal failure. Sevoflurane has not produced the expected toxicity in the same way as methoxyflurane even though significant levels of fluoride ion may result from prolonged administration. A few reasons have been theorized for the lack of nephrotoxicity of sevoflurane, even though levels of metabolically released fluoride ion can approach those of methoxyflurane. They include the fact that sevoflurane metabolism is largely hepatic rather than renal. Intrarenal production of inorganic fluoride may be a more important factor than hepatic metabolism for the nephrotoxicity produced by increased serum fluoride concentration. Sevoflurane also has a much lower blood solubility so that it undergoes rapid elimination Sevoflurane has not been associated with nephrotoxicity.12–15

Changes in renal function during barbiturate, opiate, and nitrous oxide anesthesia are similar to those observed during the administration of low-dose volatile anesthesia.¹⁶ Preoperative hydration, lower concentrations of volatile anesthetics, and maintenance of normal blood pressure attenuate reductions in renal blood flow and GFR.¹⁷

High levels of spinal or epidural anesthesia can impair venous return, diminish cardiac output, and reduce renal perfusion.¹⁸ Epidural blocks at thoracic levels with epinephrine-containing local anesthetics cause moderate reductions in renal blood flow and GFR that parallel the decrease in mean blood pressure.¹⁹ Epidural blocks performed with epinephrine-free solutions generate little change in systemic hemodynamics; however, absorption of local anesthetics is enhanced in uremic patients.²⁰

In summary, virtually all anesthetics have the potential to alter the cardiovascular system and affect renal blood flow, GFR, and urinary output. Although systolic arterial blood pressure may not fall below 80 to 90 mmHg, renal blood flow may be decreased by 30% to 40% after the administration of various anesthetics. This suggests impairment of autoregulation. In most cases, changes in renal function are transient and reversible. If they persist into the postoperative period, the cause is often a combination of factors such as preexisting renal or cardiovascular disease, severe fluid imbalance, or mismatched blood, and the importance of the anesthetic effects is decreased.

Physiologic Responses

The renal vasculature is richly innervated by the sympathetic nervous system. Drugs or perioperative events that stimulate this system cause an increase in renal vascular resistance and a decrease in renal blood flow and glomerular filtration. Surgical stress also may alter autonomic and neuroendocrine responses. Norepinephrine from sympathetic postganglionic nerve fibers and epinephrine and norepinephrine from the adrenal medulla shift blood away from the cortical nephrons; this results in decreases in renal blood flow, GFR, electrolyte excretion, and urinary output. Catecholamines also stimulate the release of renin, which ultimately leads to the production of angiotensin II, a potent vasoconstrictor.

Endocrine changes associated with anesthesia and surgical stress involve ADH, aldosterone, and the renin-angiotensin-aldosterone system. Although the perioperative period is associated with high circulating levels of ADH and aldosterone, it is not clear whether anesthetics stimulate the release or the release is secondary to the surgical stress response. General anesthetics and narcotics are thought to be minor stimuli of the release of ADH, but laparoscopic surgical procedures have been shown to increase ADH levels.²¹ Clinical studies have specifically identified that pneumoperitoneum during laparoscopic surgery increases the level of ADH.²² Other studies indicate that patients undergoing anesthetics lasting long durations had significant increases in ADH, with the greatest increase occurring at emergence.²³ Additional investigations have shown that ADH levels increase after the induction of anesthesia and is higher in subjects receiving lower concentrations of remifentanil-propofol anesthesia.²⁴

It is clear that ADH release is modulated by blood volume changes that are sensed by stretch receptors in the atrial wall. Hemorrhage, positive pressure ventilation, and the upright position increase ADH release.25,26 A decrease in arterial pressure stimulates ADH release. Distention of a balloon in the atrium, negative pressure ventilation, and immersion in water up to the neck decrease ADH release.

Renin-angiotensin levels may be elevated during the perioperative period, but the role of anesthetics and stress is not clear. Some studies have reported large increases in plasma renin levels associated with the use of anesthetics, whereas others report variances dependent on type of anesthesia delivered as well as surgical procedure. Balanced anesthesia has been found to result in higher levels of epinephrine, norepinephrine, and adrenocorticotropic hormones than total intravenous anesthesia.²⁷ The influence of renin-angiotensin on the renal effects of anesthetic agents needs further clarification. Renin levels have been shown to increase during laparoscopic surgery, as well as vasopressin, epinephrine, norepinephrine, and cortisol.²⁸ Preoperative hydration is thought to be important in the intraoperative release of renin.

Aldosterone, a hormone released from the adrenal gland, is responsible for the precise control of sodium excretion. It is not known whether anesthetic agents act directly on the adrenal gland to cause aldosterone release. They probably act indirectly through the neuroendocrine system and the renin-angiotensin-aldosterone system. Stimulation of the sympathetic nervous system causes renal vasoconstriction, which is a trigger for the renin-angiotensin-aldosterone system. Aldosterone leads to sodium and water reabsorption and can be associated with decreased urinary output.

Nephrotoxicity of Anesthetic Agents

The kidneys are extremely vulnerable to toxicity because of their rich blood supply and the increase in the concentration of excreted compounds that occurs in the renal tubules during the process of reabsorption. Medullary hyperosmolality encourages concentration of all substances, including toxins. The amount of renal damage associated with nephrotoxic agents depends on the concentration of the toxins, the degree of toxin binding to plasma proteins and nonrenal versus renal tissue, and the length of exposure of the kidneys to the toxin. The nephrotoxicity of anesthetic agents became fully appreciated in 1966, when vasopressin resistant–polyuria renal insufficiency was reported in patients receiving prolonged methoxyflurane anesthesia for abdominal surgery.²⁹ Evidence gathered indicated that the release of the inorganic fluoride ions (F⁻) in the metabolism of this fluorinated anesthetic was the causative agent in nephrotoxicity. Fortunately none of the modern inhalation anesthetics are nephrotoxic.

Isoflurane

Isoflurane is metabolized only slightly and defluorinated much less than other halogenated agents. In one report of nine surgical patients, mean peak serum fluoride concentration measured 6 hours after anesthesia was only 4.4 µmol.³²

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