Chapter 14 Lecture Outline* The Kidneys and Regulation of Water and Inorganic Ions Eric P. Widmaier Boston University Hershel Raff Medical College of Wisconsin Kevin T. Strang University of Wisconsin - Madison *See PowerPoint Image Slides for all figures and tables pre-inserted into PowerPoint without notes. Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 1 Renal Functions 2 Structure of the Urinary System Fig. 14-1 3 Functions of the Components of the Urinary System • Ureters: transport urine from kidneys to bladder • Bladder: store urine until voided from body • Urethra: carry urine from bladder to the outside of the body 4 Structure of the Kidneys Fig. 14-4 5 Nephron • Nephrons are the structural and functional units of the kidney. Each kidney has over 1 million of these units. • Each nephron consists of a glomerulus, which is a tuft of capillaries and a renal tubule. • The tubule forms a cup shape around the glomerulus called the glomerular capsule (Bowman’s capsule). 6 Juxtaglomerular Apparatus • In the arteriole wall the granular cells (juxtaglomerular cells (JG)) are enlarged smooth muscle cells that have secretory granules which contain the hormone renin (part of the reninangiotensin system (RAS). • The JG cells are mechanoreceptors (they sense blood pressure) in the afferent arteriole . • The macula densa is a group of tall, closely-packed cells that are adjacent to the granular JG cells. • The macula densa cells are chemoreceptors that respond to changes in the NaCl content of the filtrate. • These cells work in tandem and are critical regulators of blood pressure. 7 Glomerulus • The capillaries of the glomerulus are fenestrated, which allows large amounts of solute-rich fluid to pass. REMEMBER THERE SHOULD NOT BE HIGH AMOUNTS OF PROTEIN IN THE URINE! • The inner layer of the glomerular capsule contains highly modified branching epithelial cells called podocytes. • Podocytes terminate in foot processes which surround the basement membrane of the glomerulus. The clefts between the foot processes are called filtration slits. This is where the filtrate enters the capsular space. • The glomerulus also contains a smooth muscle-like cell called a glomerular mesangial cell. These cells helps regulate the blood flow in the glomerulus by contraction and engulf macromolecules that get hung up during filtration. 8 Cortical vs. Juxtamedullary Nephrons • Juxtamedullary Nephrons: – – – – Long loop of Henle Involved in the concentration of urine Found at the border between the cortex and medulla About 15% of all nephrons are in this catagory • Cortical Nephrons: – Most nephrons are in this category – Short loop of Henle 9 Basic Structure of a Nephron Fig. 14-2 10 Capillaries Associated with Nephrons • Nephrons are associated with 2 sets of capillaries: glomerular and peritubular. • The glomerular capillaries are specialized for filtration. These are the only capillaries in the body that are fed and drained by an arteriole (afferent and efferent). • This allows the blood pressure in the capillary bed to be very high and it forces fluid and solute out of the blood into the glomerular capsule. • Most of the filtrate is reabsorbed in the renal tubule cells and returns to the blood through the peritubular capillaries. 11 Basic Renal Processes Fig. 14-6 12 Glomerular Filtration • Glomerular filtration is a passive process in which hydrostatic pressures force the fluids and solute through a membrane. • The glomeruli in the kidney are a much more efficient filter than other capillary beds in the body because: 1. Filtration membrane is a large surface area and very permeable to water and solutes. 2. Glomerular pressure is higher (~55 mm Hg), so they produce 180 L vs. 3-4 formed by other capillary beds. • During filtration it is important to keep the plasma proteins in the plasma to maintain osmotic (oncotic) pressure. • If you see blood cells or protein in the urine (protinuria) then there is a problem with the filtration membrane (common finding during diabetes and hypertension that signals that kidney damage has occurred. If untreated will progress to end stage renal disease and renal failure). 13 Glomerular Filtration Fig. 14-3 14 Glomerular Filtration Fig. 14-8 15 Control of GFR by Vascular Changes Fig. 14-9 16 Tubular Reabsorption Tubular reabsorption begins as soon as filtrate enters the tubule cells. Paracellular transport occurs between cells (even though they have tight junctions) and is seen mainly with ions. Transport can be active (requires ATP) or passive (no ATP). Fig. 14-10 17 Tubular Reabsorption This transport maximum is why untreated diabetic patients have glucose in their urine. Fig. 14-11 18 Sodium Reabsorption • Na+ is the most abundant cation in the filtrate. • Na+ reabsorption is almost always active transport. • The active pumping of Na+ (via Na+/K+ ATPase) generates an electrochemical gradient that couples to passive entrance of other substances (glucose, etc.) via co-transporters. 19 Tubular Secretion • Substances such as hydrogen ion, potassium, and organic anions move from the peritubular capillaries into the tubular lumen. • Tubular secretion is an important mechanism for: 1. Disposing of drugs and drug metabolites 2. Eliminating undesired substances or end products that have reabsorbed by passive processes (urea and uric acid). 3. Removing excess K+ 4. Controlling blood pH 20 Differential Handling in the Kidney Fig. 14-7 21 Metabolism by the Tubules • Renal tubule cells can synthesize glucose during fasting and add it to the blood, and they can catabolize many organic compounds. 22 Regulation of Membrane Channels and Transporters • Regulation of reabsorption and/or secretion of many substances is achieved by regulating the activity or concentrations of the appropriate transport proteins in response to hormones and paracrine/autocrine factors. 23 “Division of Labor” in the Tubules • The majority of the reabsorption is accomplished by the proximal tubule and the loop of Henle. • Extensive reabsorption by the proximal tubule and Henle’s loop ensures that the masses of solutes and the volume of water entering the tubular segments beyond Henle’s loop are relatively small. • These distal segments then do the fine-tuning for most substances, determining the final amounts excreted in the urine by adjusting their rates of reabsorption and, in a few cases, secretion. 24 Renal Clearance (RC) • This is the volume of plasma that is cleared of a substance in one minute (mL/min). • RC=UV/P U=concentration of the substance in the urine (mg/mL) V=flow rate of urine formation (mL/min) P=concentration of substance in the plasma (mg/mL) • We use inulin because it is freely filtered and not reabsorbed and not secreted. Creatine can be used but is less accurate. It is freely filtered but also secreted in small amounts. 25 The Concept of Renal Clearance Fig. 14-12 26 Micturition • Urine is formed in the renal tubules (filtrate that is not reabsorbed) and then travels through the calyxes (major and minor) until it drains into the renal pelvis. • Fluid drains from the renal pelvis into the ureter, which then leads to the urinary bladder. • The bladder stores urine until it is excreted from the body by the micturition reflex. • Micturition is initated by a nervous reflex which causes the smooth muscle of the bladder walls to contract and the expel the urine. 27 Micturition Fig. 14-13 28 Incontinence • Incontinence is the involuntary release of urine. • The most common types are stress incontinence (due to sneezing, coughing, or exercise) and urge incontinence (associated with the desire to urinate). • Incontinence is more common in women. • Medications (such as estrogen replacement therapy to improve vaginal tone) can often relieve stress incontinence. Severe cases may require surgery to improve vaginal support of the bladder and urethra. • Any irritation to the bladder or urethra (e.g., with a bacterial infection) can cause urge incontinence. Urge incontinence can be treated with drugs such as tolterodine or oxybutin, which antagonize the effects of the parasympathetic nerves on the detrusor muscle. Because these drugs are anticholinergic, they can have side effects such as blurred vision, constipation, and increased heart rate. 29 Total-Body Balance of Sodium and Water 30 Basic Renal Processes for Sodium and Water • Sodium reabsorption is an active process occurring in all tubular segments except the descending limb of the loop of Henle. • Water reabsorption is by diffusion and is dependent upon sodium reabsorption. • Water moves through aquaporin channels. The presence of these aquaporins varies throughout the tubule segments. They are highly expressed in the proximal nephron. They are absent in the collecting ducts unless Anti-diuretic hormone (ADH) is active. 31 Primary Active Sodium Reabsorption Fig. 14-14 32 Coupling of Water Reabsorption to Sodium Reabsorption Fig. 14-15 33 Aquaporins Fig. 14-16 34 Concentration of Urine Concentration and Volume • The kidneys maintain plasma osmolarity at 300 mOsm. • They does this by using the “countercurrent mechanisms.” • Countercurrent systems in the kidney means that fluid in one tube flows the opposite way in the adjoining tube. 35 Why this Method Works • The descending loop of Henle is relatively impermeable to solutes and freely permeable to water. • The ascending limb is permeable to solutes, but not water. • Urea recycling contributes to the medullary osmotic gradient. 36 Urine Concentration: The Countercurrent Multiplier System Fig. 14-18 37 Dilute Urine • Urine is normally diluted as it moves up through the ascending limb of the loop of Henle. • To secrete dilute urine, the DCT and collecting duct cells secrete substances and then the kidney just leaves it alone. • Osmolarity can be as low as 70 mOsm. 38 Concentrated Urine • ADH uses cAMP systems to cause the insertion of aquaporins into the membranes of the principle cells of the collecting ducts. So water flows out of the collecting ducts to be reabsorbed by the body. • Urine can reach 1200 mOsm. 39 Glomerular Filtration Rate • The GFR is the volume of filtrate formed each minute. • This is affected by the volume of surface available, filtration membrane permeability and NFP, blood pressure / blood flow to the glomerular capillaries. • GFR is directly proportional to the NFP. In the absence of regulation, increases in systemic blood pressure mean increases in GFR. 40 Control of GFR Fig. 14-21 41 Control of Sodium Reabsorption Fig. 14-22 42 Control of Sodium Reabsorption Fig. 14-23 43 ANP and Sodium Excretion Fig. 14-24 44 Baroreceptor Control of Vasopressin Secretion Fig. 14-26 45 Osmoreceptor Control of Vasopressin Secretion Fig. 14-25 46 Summary Example Fig. 14-27 47 Thirst and Salt Appetite Fig. 14-28 48 Renal Regulation of Potassium Fig. 14-30 49 Aldosterone and K+ Levels Fig. 14-31 50 Renal Regulation of Calcium and Phosphate • Calcium reabsorption is increased by parathyroid hormone. • Phosphate reabosrption is decreased by parathyroid hormone. 51 Summary – Division of Labor 52 Diuretics • Diuretics are substances that promote the loss of Na+ and water. • Alcohol inhibits the release of ADH. • Osmotic diuretics----high glucose loads in urine. • Loop diuretics (lasix, furosemide) are the most powerful diuretics because they inhibit the formation of the medullar gradient. • Hydrochlorithiazide acts on the distal collecting duct. • Spironolactone is an aldosterone receptor antagonist. This is known as a K+ sparing diuretic. It acts because the K+ in the urine is from aldosterone-driven active tubular secretion into the late DCT and collecting ducts. 53 Sources of Hydrogen Ion Gain or Loss 54 Buffering of Hydrogen Ions in the Body • The major extracellular buffer is the CO2/HCO3- system. • The major intracellular buffers are phosphate and proteins. 55 Integration of Homeostatic Controls • The kidneys and the respiratory system work together to regulate hydrogen ion concentrations. 56 Renal Mechanisms • The kidneys eliminate or replenish hydrogen ions from the body by altering plasma bicarbonate concentration. 57 Bicarbonate Handling Fig. 14-32 58 Addition of New Bicarbonate to the Plasma Fig. 14-33 Fig. 14-34 59 Renal Responses to Acidosis and Alkalosis 60 Classification of Acidosis and Alkalosis 61 Kidney Disease • Many diseases affect the kidneys including: – Bacterial infections – Hypertension – Diabetes • End stage renal disease is one of the leading causes of death in the world and the leading cause of needed renal transplants. 62 Clinical Issues • Infection of the renal pelvis occurs usually by bacteria and is called pyelitis. • If it affects the whole kidney it is called pyelonephritis. • In severe cases the kidney swells, abscesses form and the pelvis fills with pus. This can result in irrepairable damage. • Antibiotics are used to treat this condition. 63 Clinical Issues • Abnormally low urine output (less the 50 mL/day) is called anuria. • This may indicate that glomerular blood pressure is too low to cause filtration. • Renal failure and anuria can result from any situation where the nephrons cease to function, including acute nephritis, transfusion reactions, and crush injuries. 64 Hemodialysis, Pertoneal Dialysis, and Transplantation Fig. 14-35 65
