Chapter 1 A Perspective on Human Genetics
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Transcript Chapter 1 A Perspective on Human Genetics
ACID BASE BALANCE
Dr.Mohammed Sharique Ahmed Quadri
Assistant professor physiology
Al Amaarefa College
Objectives
Identify the normal range of pH values, and the
upper and lower limits compatible with life.
Identify the role of kidney in regulation of acid
base balance
Explains the mechanism of reabsorption of
HCO3- and secretion of H+ by nephron
Describe the adjustments in filtered load and
HCO3 reabsorption (H+ secretion) by alterations
in systemic acid-base balance.
Describe net acid excretion by the kidneys,
treatable acid, the importance of urinary buffers,
and the production and excretion of ammonium.
Acid-Base Balance
Refers to precise regulation of free H+ concentration in body
fluids
Acids
• Group of H+ containing substances that dissociate in
solution to release free H+ and anions(H2CO3)
Bases
• Substance that can combine with free H+ and remove it
from solution(HCO3)
pH
• Designation used to express the concentration of H+
• pH 7 – neutral
• pH less than 7 → acidic
• pH greater than 7 → basic
pH
Acid-Base Balance
Arterial pH less than 6.8 or greater than 8.0 is
not compatible with life
Acidosis
• Exists when blood pH falls below 7.35
Alkalosis
• Occurs when blood pH is above 7.45
Acid-Base Balance
Consequences of fluctuations in pH
• Changes in excitability of nerve and
muscle cells
• Marked influence on enzyme activity
• Changes influence K+ levels in body
The body produces more acids than
bases
Sources of H+ in the body
• Acids taken with foods.
• Carbonic acid formation
CO2 + H20 ↔ H2CO3 ↔ H+ + HCO3• Inorganic acids produced during breakdown of
nutrients( sulfuric acid & phosphoric acid )
• Organic acids resulting from intermediary
metabolism( lactic acid)
Lines of Defense Against pH Changes
Chemical buffers :function almost immediately
(seconds to minutes).
Respiratory mechanisms :take minutes to
hours.
Renal mechanisms: may take hours to days.
First line of defense
Lines of Defense Against pH Changes
Buffer systems do not eliminate H+ from or add
them to the body but only keep them tied up until
balance can be reestablished by other mechanisms.
Buffer Systems in the Body
Bicarbonate: most important ECF buffer
H2O + CO2
H2CO3
H+ + HCO3Phosphate: important ICF and renal tubular buffer
HPO4-- + H+
H2PO4 Ammonia: important renal tubular buffer
NH3 + H+
NH4+
Proteins: important ICF and ECF buffers
Largest buffer store in the body
Albumins and globulins, such as Hb
Respiratory System
Second line of defense again changes in pH
Acts at a moderate speed
Regulates pH by controlling rate of CO2 removal
Kidneys
Third line of defense against change in
hydrogen ion concentration
Kidneys require hours to days to compensate for
changes in body-fluid pH
Control pH of body fluids by adjusting
• H+ excretion
• HCO3- excretion/ reabsorption
• Ammonia secretion
H+ secretion
In luminal membrane
H+ ATPase pump
Na – H + Antiporter
Mechanism of HCO3- Reabsorption and
Na+ - H+ Exchange
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H+ secretion in Distal & Collecting Tubule
H+ secretion and excretion couples with
addition of HCO3 to plasma
Renal handling of H+ during acidosis and
alkalosis
Under normal circumstances proximal tubular
cells and alpha intercalated cells promotes
• Net H+ secretion
• HCO3- reabsorption
This pattern of activity adjusted when pH
deviates
Control of rate of tubular secretion & H+
reabsorption
Other Urinary Buffers
the minimal urine pH is about 4.5.
In order to excrete more H+, the acid must be
buffered in tubular lumen.
H+ secreted into the tubular tubule and combines with
HPO4-2 or NH3.
HPO4-2 + H+
NH3 + H+
H2PO4-2
NH4+
Buffering of Secreted H+ by Filtered phosphate
(NaHPO4-) and Generation of “New” HCO3-
“New” HCO3-
Production and Secretion of NH4+ and HCO3- by
Proximal, Thick Loop of Henle, and Distal Tubules
H++NH3
“New” HCO3-
Acid-Base Imbalances
Can arise from either respiratory dysfunction or
metabolic disturbances
Deviations divided into four general categories
•
•
•
•
Respiratory acidosis
Respiratory alkalosis
Metabolic acidosis
Metabolic alkalosis
Respiratory Acidosis
Result of abnormal CO2 retention arising from hypoventilation
Possible causes
• Lung disease
• Depression of respiratory center by drugs or disease
• Nerve or muscle disorders that reduce respiratory muscle
activity
• Holding breath
Respiratory Acidosis
Compensations
Chemical buffers immediately take up
additional H+
Kidneys are most important in
compensating for respiratory acidosis
Respiratory Alkalosis
Primarily due to excessive loss of CO2 from body as result of
hyperventilation
Possible causes
• Fever
• Anxiety
• Aspirin poisoning
• Physiologic mechanisms at high altitude
Respiratory Alkalosis
Compensations
Chemical buffer systems liberate H+
If situation continues a few days, kidneys
compensate by conserving H+ and
excreting more HCO3-
Metabolic Acidosis
Includes all types of acidosis other than those caused by
excess CO2 in body fluids
Causes
• Severe diarrhea
• Diabetes mellitus
• Strenuous exercise
• Uremic acidosis
Metabolic Acidosis
Compensations
Buffers take up extra H+
Lungs blow off additional H+ generating CO2
Kidneys excrete more H+ and conserve more
HCO3-
Metabolic Alkalosis
Reduction in plasma pH caused by relative deficiency of
noncarbonic acids
Causes
• Vomiting
• Ingestion of alkaline drugs
Metabolic Alkalosis
Compensations
Chemical buffer systems immediately liberate H+
Ventilation is reduced
If condition persists for several days, kidneys
conserve H+ and excrete excess HCO3- in the urine
Summary of acid base abnormalities
References
Human physiology by Lauralee Sherwood, seventh
edition
Text book physiology by Guyton &Hall,11th edition
Text book of physiology by Linda .s contanzo,third
edition