renal system Flashcards
define the renal system
The renal system plays a crucial role in maintaining the body’s internal environment by regulating fluid and electrolyte balance, blood pressure, and the pH level of bodily fluids. It also helps in the elimination of metabolic waste products, toxins, and excess substances from the body through urine.
what is the gross anatomy of the renal system
- Kidneys: These bean-shaped organs filter waste products and excess substances, such as water and electrolytes, from the blood to produce urine.
- Ureters: These are muscular tubes that transport urine from the kidneys to the bladder.
- Bladder: A hollow, muscular organ that stores urine until it is excreted from the body.
- Urethra: A tube that carries urine from the bladder to outside the body during urination.
what is the functional unit of the renal system
the nephron. Nephrons are microscopic structures found in the kidneys, and they are responsible for the filtration, reabsorption, and secretion processes that occur in the formation of urine. Each kidney contains millions of nephrons, and they work together to maintain the body’s internal environment by regulating the composition and volume of urine produced.
what is the main functional difference between the ureter and urethra
ureter - transports urine from the kidneys to the bladder
urethra - carries urine from the bladder to outside the body.
what are the primary functions of the renal system
- filtration of blood
- homeostasis - fluid, electrolytes, pH, blood pressure
- excretion
- hormone production
- detoxification
what are peritubular capillaries
Peritubular capillaries surround renal tubules in the kidney. They arise from efferent arterioles and have low pressure. They enable reabsorption of water, solutes, and nutrients and facilitate secretion of waste products into tubular fluid. they regulate renal blood flow
3 process leading to urine production and where in the nephron they occur
- filtration - blood pressure forces fluid and small solutes out of glomerular capillaries and into bowman’s capsule - occurs in renal corpuscle
- reabsorption - substances in filtrate are selectively reabsorbed into the blood through peritubular capillaries - occurs along the renal tubule (proximal convoluted tubule)
- secretion - substances are activel transported from blood to peritubular capillaries - occurs in distal convoluted tubule
describe the structural arrangement of the nephron from the glomerulus to pelvis
- Glomerulus: begins in glomerulus, supplied by an afferent arteriole/drained by an efferent arteriole. Blood is filtered here small molecules and ions are forced out of the blood into the Bowman’s capsule due to blood pressure.
- Bowman’s Capsule (Glomerular Capsule): Surrounding the glomerulus it is a double-walled cup-shaped structure that collects the filtrate from the glomerulus.
- Proximal Convoluted Tubule (PCT): filtrate enters the proximal convoluted tubule, the majority of reabsorption occurs here. it has microvilli, increasing surface area for reabsorption
- Loop of Henle:
The PCT leads to the loop of Henle
Descending Limb: It descends into the medulla of the kidney, permeable to water but impermeable to ions.
Ascending Limb: The ascending limb ascends back towards the cortex. It is impermeable to water but actively transports ions - Distal Convoluted Tubule (DCT):
The ascending limb of the loop of Henle leads to the distal convoluted tubule. it is involved in further reabsorption of ions and regulation of electrolyte balance. - Collecting Duct: several nephrons drain into a single collecting duct. They extend through the medulla towards the renal pelvis.
Cortical Collecting Duct: Initially located in the cortex, it receives fluid from multiple nephrons.
Medullary Collecting Duct: As it descends into the medulla, it merges with other collecting ducts and continues towards the renal pelvis.
The collecting ducts are responsible for further reabsorption of water and regulation of urine concentration under the influence of hormones like antidiuretic hormone (ADH).
- Renal Papilla and Renal Pelvis:
The collecting ducts converge towards the renal papilla, located at the tip of the renal pyramid in the medulla.
Urine from multiple collecting ducts drains into the renal pelvis, a funnel-shaped structure that collects urine and transports it towards the ureter, which leads to the urinary bladder.
describe the structural differences between the two types of nephrons and describe how their structure facilitates their function
- cortical nephrons: Location: outer cortex
Renal Corpuscle: The glomeruli are located relatively close to the kidney’s surface
Loop of Henle: The loop of Henle has a relatively short descending limb that extends only a short distance into the medulla before turning back towards the cortex.
Function: produces urine and maintains overall body fluid and electrolyte balance. - Juxtamedullary Nephrons:
Location: Near the corticomedullary junction, deeper into the renal medulla.
Renal Corpuscle: The glomeruli are located deeper in the cortex
Loop of Henle: have a long loop of Henle that extends deep into the medulla, with a long descending limb and an ascending limb that runs parallel to the descending limb.
Function: plays a crucial role in the kidney’s ability to produce concentrated urine. The long loop of Henle allows for greater countercurrent multiplication, facilitating the reabsorption of water and concentration of urine.
define glomerular filtrate and quote typical values for males and females
Glomerular filtrate refers to the fluid that is initially filtered from the blood within the glomerular capillaries into the Bowman’s capsule
- based on factors such as age, body size, and overall health status, common estimate for GFR in healthy adults is approximately 90 to 120 milliliters per minute (mL/min) or about 125 to 175 liters per day.
how does ultrafiltration occur in the renal corpuscle outlining the structural components involved
- Glomerular Capillaries (Glomerulus): consists of a dense network of fenestrated capillaries with large pores. Blood enters the glomerulus through an afferent arteriole and exits via an efferent arteriole with the relatively high hydrostatic pressure
- Bowman’s Capsule (Glomerular Capsule): surrounds the glomerulus, consists of an inner visceral layer and an outer parietal layer.
The visceral layer is composed of specialized epithelial cells called podocytes.
The space between the visceral and parietal layers forms the Bowman’s space or urinary space, which collects the filtrate. - Filtration Barrier: formed by three layers: the fenestrated endothelium, the basement membrane, and the slit diaphragms
The fenestrated endothelium allows small molecules to pass through but prevents larger molecules the basement membrane acts as a molecular sieve
The slit diaphragms between podocyte pedicels are negatively charged and repel negatively charged proteins, enhancing the selectivity of filtration. - Ultrafiltration Process:
Blood plasma enters the glomerular capillaries under pressure
Small molecules, ions and waste products pass freely through the filtration barrier, larger molecules and blood cells are retained in the bloodstream glomerular filtrate
what are the main differences between afferent and efferent arterioles
- direction: A - oxygenated blood from renal artery into glomerulus E - away from glomerulus
- structure: A - wider E - narrower
- pressure/flow: A - high pressure and regulates in flow E - increased pressure and regulates out flow
- filtration: A - from blood plasma into the bowman’s capsule E - filtration and regulation of glomerular filtration rate
describe the process that occurs in the proximal convoluted tubule
- Reabsorption of Water and Solutes: highly permeable to water and solutes due to the presence of numerous microvilli approximately 65-70% of filtered sodium ions (Na⁺) and water are reabsorbed in the PCT sodium ions are actively transported out of the tubular lumen into the interstitial fluid by sodium-potassium pumps this creates a concentration gradient that drives the passive reabsorption of other solutes glucose and amino acids are reabsorbed via secondary active transport
- Reabsorption of Nutrients: reabsorbs most of the filtered glucose and amino acids to prevent their loss in the urine. they are reabsorbed from the tubular lumen into the epithelial cells of the PCT then transported out of the cells into the interstitial fluid and subsequently into the peritubular capillaries
- Reabsorption of Bicarbonate Ions: bicarbonate ions (HCO₃⁻) are reabsorbed in the PCT to help maintain acid-base balance in the body via a process involving the exchange of bicarbonate ions for chloride ions (Cl⁻) across the apical membrane of the epithelial cells.
- Secretion of Waste Products: the PCT also plays a role in the secretion of waste products and certain ions occurs through both active and passive transport processes, involving specific transporter proteins
describe the process that occurs in the distal convoluted tubule
- Selective Reabsorption:
reabsorption of sodium ions (Na⁺), chloride ions (Cl⁻), and calcium ions (Ca²⁺) under the influence of various hormones. sodium reabsorption in the DCT is regulated by aldosterone, reabsorption from the tubular lumen into the interstitial fluid. Chloride ions can also be reabsorbed - Regulation of Potassium and Hydrogen Ions: involved in the secretion of potassium ions (K⁺) and hydrogen ions (H⁺) into the tubular fluid. to help regulate potassium and acid-base balance in the body.
Potassium secretion occurs through potassium channels and aldosterone stimulates it Hydrogen ions are secreted into the tubular fluid via a process involving hydrogen-potassium exchange. - Calcium Reabsorption: is responsible for the reabsorption of calcium ions (Ca²⁺) under the influence of parathyroid hormone (PTH).
- Final Adjustment of Urine Composition: by adjusting the reabsorption and secretion of electrolytes and ions based on the body’s needs and hormonal signals.
It helps regulate blood pressure, electrolyte balance, and acid-base balance
describe the process that occurs in the collecting ducts
- Reabsorption of Water:
controls the concentration and volume of urine. permeability is regulated by the antidiuretic hormone (ADH). ADH is released by the posterior pituitary gland in response to changes in blood osmolarity or blood volume.
it becomes more permeable to water. - Reabsorption and Secretion of Ions: sodium reabsorption in the collecting ducts can occur via passive diffusion or active transport
Potassium secretion is regulated by aldosterone. Hydrogen ions can be secreted into the tubular fluid to regulate acid-base balance, while bicarbonate ions may be reabsorbed to help buffer excess hydrogen ions. - Final Adjustment of Urine Composition: determines the final composition of urine by adjusting the reabsorption and secretion of water and solutes to help regulate electrolyte balance, acid-base balance, and fluid balance the composition leaving the collecting ducts is finely tuned to maintain homeostasis