Acid Base Balance, Animation.

Alila Medical Media

10 Oct 201705:45

Summary

TLDRThe script explains the critical role of pH in maintaining blood's acidity within a precise range of 7.35 to 7.45. It details the body's two main mechanisms for acid-base regulation: pulmonary elimination of carbon dioxide and renal excretion of hydrogen ions. The equilibrium between carbon dioxide, carbonic acid, hydrogen ions, and bicarbonate is central to this regulation. The script further delves into how metabolic and respiratory acidosis and alkalosis affect this balance, highlighting the importance of bicarbonate and ammonia in buffering systems.

Takeaways

📊 pH is a crucial measure of acidity, with the blood's pH tightly regulated between 7.35 and 7.45 to ensure protein stability and biochemical processes.
🌡️ Even minor pH changes can have significant impacts on the body, highlighting the importance of maintaining a narrow pH range.
🔄 Cellular metabolism produces carbon dioxide, which combines with water to form carbonic acid, leading to an equilibrium of hydrogen ions and bicarbonate.
⚖️ The equilibrium of carbonic acid and its dissociation products is central to understanding how the body regulates acid-base balance.
➡️ Increased carbon dioxide production by cells drives the equilibrium to produce more hydrogen ions, making the blood more acidic and lowering pH.
💨 The body maintains pH balance through two primary mechanisms: elimination of carbon dioxide via exhalation and excretion of hydrogen ions and reabsorption of bicarbonate by the kidneys.
🏃‍♂️ Pulmonary regulation is a fast response to pH changes, with chemoreceptors triggering deeper, faster breathing to exhale more carbon dioxide and restore pH balance.
🚰 Renal regulation is slower, taking days to adjust the excretion of acids and reabsorption of bicarbonate in response to pH disturbances.
🔧 The kidneys regulate blood pH by adjusting the reabsorption of bicarbonate in the proximal tubule and the secretion of acids in the collecting duct.
🧪 The ammonia buffering system in the kidneys is vital for pH regulation, as it can increase ammonia production to buffer excess acids when needed.
🧬 Pathologic changes can lead to acid-base disturbances, with acidosis increasing acidity and alkalosis increasing alkalinity, potentially resulting in normal, acidic, or basic blood pH.
🌪️ Respiratory acidosis occurs when lung function is inadequate, leading to carbon dioxide accumulation, while metabolic acidosis results from excessive metabolic acid production or decreased renal acid excretion.

Q & A

What is pH and why is it important for the body?
-pH is a measure of acidity or alkalinity, with the body's blood pH being strictly regulated between 7.35 and 7.45 to ensure protein stability and proper biochemical processes.
How does normal cellular metabolism affect blood pH?
-Normal cellular metabolism produces carbon dioxide, which combines with water to form carbonic acid, dissociating into hydrogen ions and bicarbonate. This process can make the blood more acidic, thus affecting the pH.
What is the role of the equilibrium in acid-base regulation?
-The equilibrium between carbon dioxide, water, carbonic acid, hydrogen ions, and bicarbonate is central to acid-base regulation, as changes in the concentration of one component will affect the others and shift the equilibrium.
How does the body respond to increased acidity in the blood?
-The body responds by eliminating carbon dioxide through exhalation and excreting hydrogen ions and reabsorbing bicarbonate through the kidneys to maintain the blood pH within normal limits.
What is the difference between pulmonary and renal regulation of blood pH?
-Pulmonary regulation is the elimination of carbon dioxide through exhalation, which is fast and effective within minutes to hours. Renal regulation involves the kidneys adjusting the amount of excreted acids and reabsorbed bicarbonate, which is slower and takes days to respond to pH disturbances.
How do the kidneys control blood pH?
-The kidneys control blood pH by adjusting the amount of acids excreted and bicarbonate reabsorbed. They regulate the reabsorption of bicarbonate in the proximal tubule and the secretion of acids in the collecting duct.
What is the significance of the ammonia buffering system in the kidneys?
-The ammonia buffering system is important because it can regulate ammonia production in response to changes in acidity, allowing the concentration of ammonia to increase when necessary to buffer hydrogen ions and maintain pH balance.
What factors other than blood pH can influence acid excretion?
-Factors such as potassium, chloride concentrations, and several hormones also play important roles in influencing acid excretion.
What are the two types of acidosis and their causes?
-Acidosis can be respiratory, caused by inadequate lung function leading to carbon dioxide accumulation, or metabolic, resulting from excessive production of metabolic acids, decreased kidney excretion, ingestion of acids, or loss of alkali.
How is metabolic acidosis characterized in terms of plasma bicarbonate?
-Metabolic acidosis is characterized by a primary decrease in plasma bicarbonate.
What are the two types of alkalosis and their causes?
-Alkalosis can be respiratory, caused by increased ventilation leading to excessive exhalation of carbon dioxide, or metabolic, resulting from excess loss of acids, bicarbonate retention, or ingestion of alkali.
How is metabolic alkalosis characterized in terms of plasma bicarbonate?
-Metabolic alkalosis is characterized by a primary increase in plasma bicarbonate.