Cortical and Juxtamedullary Nephrons

• Understand the morphological relationships between the kidney tubules and the circulatory system
• Analyze experimental data for calculating glomerular filtration rate
• Set up and perform a perfusion of renal tubules, including the calculation of liquid absorption rates
• Learn about the epithelial transport mechanism in the kidney tubules
• Use experimental data to assess the mode of action of a diuretic drug

Kidneys play a critical role in the filtration and reabsorption of essential substances that are required for the body. In this simulation, you will explore the anatomy of the kidney through 3D holograms and identify the physiological roles in maintaining homeostasis as well as the factors that influence urine regulation.

In this simulation, you will use the kidney from a dissected rat to study the mode of action of a new diuretic drug and learn the reabsorption process in the renal tubules. You will learn how to calculate the glomerular filtration rate or GFR and learn the hormones that influence urine output. At the end of the simulation, you should be able to correlate the relationship between renal and circulatory systems in controlling blood pressure.

 

Part 1: Complete Labster- Renal Physiology: Find the mode of action of a diuretic drug

Part 2: Report and Reflection

Purpose: Describe in your own words and in complete sentences the purpose of this experiment.

Observations: List 2 observations you have made in this simulation.

Answer all the questions below:

1. In the simulation, why was the ascending limb of the nephron selected to study the effect of the diuretic drug? (2 points)
2. What is renal perfusion and how does it affect blood pressure? (2 points)
3. Compare and contrast the cortical and Juxtamedullary nephrons. (2 points)
4. What are the hormones that regulate urine output? (2 points)
5. What is countercurrent multiplication in a nephron and how does it affect the urine concentration? (2 points)
6. Reflection: Reflect on at least 2 key concepts you have learned from this simulation.

How can you apply it to human health and diseases?

Part 1: Complete Labster- Renal Physiology: Find the mode of action of a diuretic drug

In this part of the simulation, you will study the mode of action of a diuretic drug using the kidney from a dissected rat. You will focus on the ascending limb of the nephron to understand how the drug affects the reabsorption process in the renal tubules.

Part 2: Report and Reflection

Purpose of the Experiment:

The purpose of this experiment is to investigate the mode of action of a diuretic drug in the context of renal physiology. The diuretic drug is known to increase urine output, but the specific mechanism by which it accomplishes this is not well understood. By studying the effect of the drug on the ascending limb of the nephron, researchers aim to gain insights into the drug’s impact on renal tubule function and the reabsorption process. This knowledge is essential for understanding how diuretics can be used as therapeutic agents in managing conditions related to fluid and electrolyte balance.

Observations:

1. Increased Urine Output: During the simulation, you may observe a significant increase in urine production after administering the diuretic drug. This observation confirms the drug’s diuretic effect.
2. Decreased Sodium Reabsorption: Another observation could be a decrease in the reabsorption of sodium in the ascending limb of the nephron. This alteration in sodium transport is likely to contribute to the increased urine output.

Answering the Questions:

1. Why was the ascending limb of the nephron selected to study the effect of the diuretic drug?

The ascending limb of the nephron was selected to study the effect of the diuretic drug because it plays a crucial role in the reabsorption of sodium and water. The ascending limb is impermeable to water but actively reabsorbs sodium through a process that involves the sodium-potassium-chloride cotransporter (NKCC2). By targeting this segment of the nephron, researchers can investigate how the diuretic drug interferes with sodium reabsorption, leading to increased sodium excretion and subsequent water loss, resulting in diuresis.

2. What is renal perfusion, and how does it affect blood pressure?

Renal perfusion refers to the blood flow delivered to the kidneys. It plays a vital role in regulating blood pressure. When the kidneys receive an adequate amount of blood, they can effectively filter and excrete waste products, regulate electrolyte balance, and maintain fluid homeostasis. Proper renal perfusion is essential for the activation of the renin-angiotensin-aldosterone system (RAAS), which helps regulate blood pressure by controlling the balance of sodium and water in the body. Any disruption in renal perfusion can lead to imbalances in blood pressure and contribute to hypertension or low blood pressure.

3. Compare and contrast the cortical and Juxtamedullary nephrons.

Cortical Nephrons:

• Majority of nephrons in the kidney (around 85%)
• Their glomeruli are located in the outer cortex of the kidney.
• Short loops of Henle that extend into the outer medulla.
• Involved in regulating the concentration of urine and reabsorbing essential substances.
• Play a role in maintaining electrolyte balance and acid-base homeostasis.

Juxtamedullary Nephrons:

• Comprise a smaller percentage of nephrons (around 15%)
• Their glomeruli are located near the boundary of the cortex and medulla.
• Have long loops of Henle that extend deep into the medulla.
• Play a crucial role in establishing the concentration gradient in the medulla, which is essential for urine concentration and water conservation.
• Enable the kidney to produce concentrated urine and are involved in the body’s water conservation mechanisms.

4. What are the hormones that regulate urine output?

The hormones that regulate urine output include:

• Antidiuretic hormone (ADH), also known as vasopressin, which is released by the posterior pituitary gland. ADH acts on the collecting ducts of the nephron to increase water reabsorption, thereby reducing urine output and helping conserve water.
• Aldosterone, a hormone produced by the adrenal glands, primarily targets the distal convoluted tubules and collecting ducts. It enhances sodium reabsorption and potassium secretion, which affects water reabsorption and ultimately influences urine volume.
• Atrial natriuretic peptide (ANP), which is produced by the heart in response to increased blood volume and pressure. ANP acts on the glomerulus and collecting ducts, inhibiting sodium reabsorption and increasing urine output to reduce blood volume and pressure.

5. What is countercurrent multiplication in a nephron, and how does it affect urine concentration?

Countercurrent multiplication refers to the process that occurs in the loop of Henle of juxtamedullary nephrons, where a concentration gradient is established in the medullary interstitium. This process is essential for the kidney’s ability to produce concentrated urine. The countercurrent multiplier system involves a counter-flow exchange of solutes and water in the descending and ascending limbs of the loop of Henle.

The descending limb is permeable to water but not to solutes, so as the tubular fluid descends into the medulla, it loses water to the surrounding interstitium, leading to an increase in solute concentration.

The ascending limb, on the other hand, is impermeable to water but actively transports solutes (sodium, potassium, chloride) out of the tubular fluid, further increasing the interstitial solute concentration.

This countercurrent exchange mechanism leads to the establishment of a concentration gradient in the medullary interstitium, with the highest concentration of solutes at the deepest part of the medulla. This gradient drives water reabsorption from the collecting ducts, leading to the production of concentrated urine.

Reflection:

1. Significance of Diuretics: One key concept learned from this simulation is the mode of action of diuretic drugs in increasing urine output. Understanding how diuretics affect specific nephron segments, such as the ascending limb, is crucial for their targeted use in managing conditions like edema and hypertension. Applying this knowledge to human health can lead to better treatment strategies for patients with fluid and electrolyte imbalances.
2. Role of Nephron Segments: Another key concept is the importance of different nephron segments in urine concentration and regulation. The distinction between cortical and juxtamedullary nephrons and their unique roles in maintaining homeostasis provides insights into the kidney’s intricate functions. Understanding these mechanisms can help identify the root causes of certain kidney diseases and inform therapeutic interventions.

Application to Human Health and Diseases:

The knowledge gained from this simulation can be applied to various aspects of human health and diseases related to the kidney and fluid balance:

• Understanding Diuretic Therapy: The insights gained from studying diuretic drugs’ mode of action can aid in developing more effective and targeted diuretic therapies. This can benefit patients with conditions such as congestive heart failure, kidney stones, and hypertension.
• Managing Fluid and Electrolyte Imbalances: Understanding the renal tubular transport mechanisms can help in diagnosing and treating disorders like hyponatremia, hyperkalemia, and acid-base imbalances.
• Kidney Diseases: Knowledge of the countercurrent multiplier system and its impact on urine concentration can be crucial in understanding the pathophysiology of conditions like diabetes