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Fundamentals of Anatomy and Physiology: 17.15 Disorders of Acid-Base Balance

Fundamentals of Anatomy and Physiology
17.15 Disorders of Acid-Base Balance
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table of contents
  1. Cover
  2. Title Page
  3. Copyright
  4. Table Of Contents
  5. About the Authors
  6. Acknowledgments
  7. Preface
  8. Levels of Organisation, Homeostasis and Nomenclature
    1. 1.1 Overview of Anatomy and Physiology
    2. 1.2 Structural Organisation of the Human Body
    3. 1.3 Homeostasis
    4. 1.4 Anatomical Terminology
  9. Cells and Reproduction
    1. 2.1 Synthesis of Biological Macromolecules
    2. 2.2 Carbohydrates
    3. 2.3 Lipids
    4. 2.4 Protein
    5. 2.5 Nucleic Acid
    6. 2.6 The Cell Membrane
    7. 2.7 The Cytoplasm and Cellular Organelles
    8. 2.8 The Nucleus and DNA Replication
    9. 2.9 Protein Synthesis
    10. 2.10 Cell Growth and Division
    11. 2.11 Cellular Differentiation
  10. Tissues, Organs, Systems
    1. 3.1 Types of Tissues
    2. 3.2 Epithelial Tissue
    3. 3.3 Connective Tissue Supports and Protects
    4. 3.4 Muscle Tissue and Motion
    5. 3.5 Nervous Tissue Mediates Perception and Response
    6. 3.6 Tissue Injury and Ageing
  11. Integumentary System
    1. 4.1 Layers of the Skin
    2. 4.2 Accessory Structures of the Skin
    3. 4.3 Functions of the Integumentary System
    4. 4.4 Diseases, Disorders and Injuries of the Integumentary System
  12. Blood
    1. 5.1 An Overview of Blood
    2. 5.2 Production of the Formed Elements
    3. 5.3 Erythrocytes
    4. 5.4 Leukocytes and Platelets
    5. 5.5 Haemostasis
    6. 5.6 Blood Typing
  13. Cardiovascular System
    1. 6.1 Heart Anatomy
    2. 6.2 Cardiac Muscle and Electrical Activity
    3. 6.3 Cardiac Cycle
    4. 6.4 Cardiac Physiology
    5. 6.5 Development of the Heart
    6. 6.6 Structure and Function of Blood Vessels
    7. 6.7 Blood Flow, Blood Pressure and Resistance
    8. 6.8 Capillary Exchange
    9. 6.9 Homeostatic Regulation of the Vascular System
    10. 6.10 Circulatory Pathways
    11. 6.11 Development of Blood Vessels and Foetal Circulation
  14. Lymphatic System and Immunity
    1. 7.1 Anatomy of the Lymphatic and Immune Systems
    2. 7.2 Barrier Defences and the Innate Immune Response
    3. 7.3 The Adaptive Immune Response: T Lymphocytes and their Functional Types
    4. 7.4 The Adaptive Immune Response: B-Lymhocytes and Antibodies
    5. 7.5 The Immune Response Against Pathogens
    6. 7.6 Diseases Associated with Depressed or Overactive Immune Responses
    7. 7.7 Transplantation and Cancer Immunology
  15. Respiratory System
    1. 8.1 Organs and Structures of the Respiratory System
    2. 8.2 The Lungs
    3. 8.3 The Process of Breathing
    4. 8.4 Gas Exchange
    5. 8.5 Transport of Gases
    6. 8.6 Modifications in Respiratory Functions
    7. 8.7 Embryonic Development of the Respiratory System
  16. Muscle System
    1. 9.1 Overview of Muscle Tissues
    2. 9.2 Skeletal Muscle
    3. 9.3 Muscle Fibre Contraction and Relaxation
    4. 9.4 Nervous System Control of Muscle Tension
    5. 9.5 Types of Muscle Fibres
    6. 9.6 Exercise and Muscle Performance
    7. 9.7 Cardiac Muscle Tissue
    8. 9.8 Smooth Muscle
    9. 9.9 Development and Regeneration of Muscle Tissue
  17. Skeletal System
    1. 10.1 The Functions of the Skeletal System
    2. 10.2 Bone Classification
    3. 10.3 Bone Structure
    4. 10.4 Bone Formation and Development
    5. 10.5 Fractures: Bone Repair
    6. 10.6 Exercise, Nutrition, Hormones and Bone Tissue
    7. 10.7 Calcium Homeostasis: Interactions of the Skeletal System and Other Organ Systems
    8. 10.8 Divisions of the Skeletal System
    9. 10.9 The Skull
    10. 10.10 The Vertebral Column
    11. 10.11 The Thoracic Cage
    12. 10.12 Embryonic Development of the Axial Skeleton
  18. Musculoskeletal System
    1. 11.1 The Pectoral Girdle
    2. 11.2 Bones of the Upper Limb
    3. 11.3 The Pelvic Girdle and Pelvis
    4. 11.4 Bones of the Lower Limb
    5. 11.5 Development of the Appendicular Skeleton
    6. 11.6 Classification of Joints
    7. 11.7 Fibrous Joints
    8. 11.8 Cartilaginous Joints
    9. 11.9 Synovial Joints
    10. 11.10 Types of Body Movements
    11. 11.11 Anatomy of Selected Synovial Joints
    12. 11.12 Development of Joints
  19. Digestive System
    1. 12.1 Overview of the Digestive System
    2. 12.2 Digestive System Processes and Regulation
    3. 12.3 The Mouth, Pharynx and Oesophagus
    4. 12.4 The Stomach
    5. 12.5 The Small and Large Intestines
    6. 12.6 Accessory Organs in Digestion: the Liver, Pancreas and Gallbladder
    7. 12.7 Chemical Digestion and Absorption
  20. Nervous System
    1. 13.1 Basic Structure and Function of the Nervous System
    2. 13.2 Nervous Tissue
    3. 13.3 The Function of Nervous Tissue
    4. 13.4 The Action Potential
    5. 13.5 Communication between Neurons
    6. 13.6 The Embyrologic Perspective
    7. 13.7 The Central Nervous System
    8. 13.8 Circulation and the Central Nervous System
    9. 13.9 The Peripheral Nervous System
    10. 13.10 Sensory Perception
    11. 13.11 Central Processing
    12. 13.12 Motor Responses
  21. Endocrine System
    1. 14.1 An Overview of the Endocrine System
    2. 14.2 Hormones
    3. 14.3 The Pituitary Gland and Hypothalamus
    4. 14.4 The Thyroid Gland
    5. 14.5 The Parathyroid Glands
    6. 14.6 The Adrenal Glands
    7. 14.7 The Pineal Gland
    8. 14.8 Gonadal and Placental Hormones
    9. 14.9 The Endocrine Pancreas
    10. 14.10 Organs with Secondary Endocrine Functions
    11. 14.11 Development and Ageing of the Endocrine System
  22. Reproductive System
    1. 15.1 Anatomy and Physiology of the Male Reproductive System
    2. 15.2 Anatomy and Physiology of the Female Reproductive System
    3. 15.3 Development of the Male and Female Reproductive Systems
  23. Pregnancy and Human Development
    1. 16.1 Fertilisation
    2. 16.2 Embryonic Development
    3. 16.3 Foetal Development
  24. Urinary System
    1. 17.1 Physical Characteristics of Urine
    2. 17.2 Gross Anatomy of Urine Transport
    3. 17.3 Gross Anatomy of the Kidney
    4. 17.4 Microscopic Anatomy of the Kidney
    5. 17.5 Physiology of Urine Formation
    6. 17.6 Tubular Reabsorption
    7. 17.7 Regulation of Renal Blood Flow
    8. 17.8 Endocrine Regulation of Kidney Function
    9. 17.9 Regulation of Fluid Volume and Composition
    10. 17.10 The Urinary System and Homeostasis
    11. 17.11 Body Fluids and Fluid Compartments
    12. 17.12 Water Balance
    13. 17.13 Electrolyte Balance
    14. 17.14 Acid-Base Balance
    15. 17.15 Disorders of Acid-Base Balance
  25. Appendix A: Unit Measurements and Calculations
  26. Appendix B: Chemical Abbreviations
  27. Glossary
  28. Bibliography

17.15 Disorders of Acid-Base Balance

Learning Objectives

By the end of this section, you will be able to:

  • Identify the three blood variables considered when making a diagnosis of acidosis or alkalosis
  • Identify the source of compensation for blood pH problems of a respiratory origin
  • Identify the source of compensation for blood pH problems of a metabolic/renal origin

Normal arterial blood pH is restricted to a very narrow range of 7.35 to 7.45. A person who has a blood pH below 7.35 is considered to be in acidosis (actually, “physiological acidosis,” because blood is not truly acidic until its pH drops below 7), and a continuous blood pH below 7.0 can be fatal. Acidosis has several symptoms, including headache and confusion, and the individual can become lethargic and easily fatigued (Figure 17.15.1). A person who has a blood pH above 7.45 is considered to be in alkalosis, and a pH above 7.8 is fatal. Some symptoms of alkalosis include cognitive impairment (which can progress to unconsciousness), tingling or numbness in the extremities, muscle twitching and spasm, and nausea and vomiting. Both acidosis and alkalosis can be caused by either metabolic or respiratory disorders.

As discussed earlier in this chapter, the concentration of carbonic acid in the blood is dependent on the level of CO2 in the body and the amount of CO2 gas exhaled through the lungs. Thus, the respiratory contribution to acid-base balance is usually discussed in terms of CO2 (rather than of carbonic acid). Remember that a molecule of carbonic acid is lost for every molecule of CO2 exhaled, and a molecule of carbonic acid is formed for every molecule of CO2 retained.

Symptoms of acidosis and alkalosis in diagram
Figure 17.15.1. Symptoms of acidosis and alkalosis. Symptoms of acidosis affect several organ systems. Both acidosis and alkalosis can be diagnosed using a blood test.

Metabolic Acidosis: Primary Bicarbonate Deficiency

Metabolic acidosis occurs when the blood is too acidic (pH below 7.35) due to too little bicarbonate, a condition called primary bicarbonate deficiency. At the normal pH of 7.40, the ratio of bicarbonate to carbonic acid buffer is 20:1. If a person’s blood pH drops below 7.35, then he or she is in metabolic acidosis. The most common cause of metabolic acidosis is the presence of organic acids or excessive ketones in the blood. Table 17.15.1 lists some other causes of metabolic acidosis.

Table 17.15.1. Common causes of metabolic acidosis and blood metabolites

CauseMetabolite
DiarrhoeaBicarbonate
UraemiaPhosphoric, sulfuric, and lactic acids
Diabetic ketoacidosisIncreased ketones
Strenuous exerciseLactic acid
MethanolFormic acid*
Paraldehydeβ-Hydroxybutyric acid*
IsopropanolPropionic acid*
Ethylene glycolGlycolic acid, and some oxalic acids and formic acids*
Salicylate/aspirinSulfosalicylic acid (SSA)*
* Acid metabolites from ingested chemical

The first three of the eight causes of metabolic acidosis listed are medical (or unusual physiological) conditions. Strenuous exercise can cause temporary metabolic acidosis due to the production of lactic acid. The last five causes result from the ingestion of specific substances. The active form of aspirin is its metabolite, sulfasalicylic acid. An overdose of aspirin causes acidosis due to the acidity of this metabolite. Metabolic acidosis can also result from uraemia, which is the retention of urea and uric acid. Metabolic acidosis can also arise from diabetic ketoacidosis, wherein an excess of ketones is present in the blood. Other causes of metabolic acidosis are a decrease in the excretion of hydrogen ions, which inhibits the conservation of bicarbonate ions, and excessive loss of bicarbonate ions through the gastrointestinal tract due to diarrhoea.

Metabolic Alkalosis: Primary Bicarbonate Excess

Metabolic alkalosis is the opposite of metabolic acidosis. It occurs when the blood is too alkaline (pH above 7.45) due to too much bicarbonate (called primary bicarbonate excess).

A transient excess of bicarbonate in the blood can follow ingestion of excessive amounts of bicarbonate, citrate, or antacids for conditions such as stomach acid reflux—known as heartburn. Cushing’s disease, which is the chronic hypersecretion of adrenocorticotrophic hormone (ACTH) by the anterior pituitary gland, can cause chronic metabolic alkalosis. The oversecretion of ACTH results in elevated aldosterone levels and an increased loss of potassium by urinary excretion. Other causes of metabolic alkalosis include the loss of hydrochloric acid from the stomach through vomiting, potassium depletion due to the use of diuretics for hypertension, and the excessive use of laxatives.

Respiratory Acidosis: Primary Carbonic Acid/CO2 Excess

Respiratory acidosis occurs when the blood is overly acidic due to an excess of carbonic acid, resulting from too much CO2 in the blood. Respiratory acidosis can result from anything that interferes with respiration, such as pneumonia, emphysema, or congestive heart failure.

Respiratory Alkalosis: Primary Carbonic Acid/CO2 DEFICIENCY

Respiratory alkalosis occurs when the blood is overly alkaline due to a deficiency in carbonic acid and CO2 levels in the blood. This condition usually occurs when too much CO2 is exhaled from the lungs, as occurs in hyperventilation, which is breathing that is deeper or more frequent than normal. An elevated respiratory rate leading to hyperventilation can be due to extreme emotional upset or fear, fever, infections, hypoxia, or abnormally high levels of catecholamines, such as adrenaline and noradrenaline. Surprisingly, aspirin overdose—salicylate toxicity—can result in respiratory alkalosis as the body tries to compensate for initial acidosis.

Compensation Mechanisms

Various compensatory mechanisms exist to maintain blood pH within a narrow range, including buffers, respiration and renal mechanisms. Although compensatory mechanisms usually work very well, when one of these mechanisms is not working properly (like kidney failure or respiratory disease), they have their limits. If the pH and bicarbonate to carbonic acid ratio are changed too drastically, the body may not be able to compensate. Moreover, extreme changes in pH can denature proteins. Extensive damage to proteins in this way can result in disruption of normal metabolic processes, serious tissue damage and ultimately, death.

Respiratory Compensation

Respiratory compensation for metabolic acidosis increases the respiratory rate to drive off CO2 and readjust the bicarbonate to carbonic acid ratio to the 20:1 level. This adjustment can occur within minutes. Respiratory compensation for metabolic alkalosis is not as adept as its compensation for acidosis. The normal response of the respiratory system to elevated pH is to increase the amount of CO2 in the blood by decreasing the respiratory rate to conserve CO2. There is a limit to the decrease in respiration, however, that the body can tolerate. Hence, the respiratory route is less efficient at compensating for metabolic alkalosis than for acidosis.

Metabolic Compensation

Metabolic and renal compensation for respiratory diseases that can create acidosis revolves around the conservation of bicarbonate ions. In cases of respiratory acidosis, the kidney increases the conservation of bicarbonate and secretion of H+ through the exchange mechanism discussed earlier. These processes increase the concentration of bicarbonate in the blood, re-establishing the proper relative concentrations of bicarbonate and carbonic acid. In cases of respiratory alkalosis, the kidneys decrease the production of bicarbonate and reabsorb H+ from the tubular fluid. These processes can be limited by the exchange of potassium by the renal cells, which use a K+-H+ exchange mechanism (antiporter).

Diagnosing Acidosis and Alkalosis

Lab tests for pH, CO2 partial pressure (pCO2) and HCO3– can identify acidosis and alkalosis, indicating whether the imbalance is respiratory or metabolic, and the extent to which compensatory mechanisms are working. The blood pH value, as shown in Table 17.15.2, indicates whether the blood is in acidosis, the normal range, or alkalosis. The pCO2 and total HCO3– values aid in determining whether the condition is metabolic or respiratory, and whether the patient has been able to compensate for the problem. Table 17.15.2 lists the conditions and laboratory results that can be used to classify these conditions. Metabolic acid-base imbalances typically result from kidney disease and the respiratory system usually responds to compensate.

Table 17.15.2. Types of acidosis and alkalosis

 pHpCO2Total HCO3–
Metabolic acidosisDecreasesNormal, then decreasesDecreases
Respiratory acidosisDecreasesIncreasesNormal, then increases
Metabolic alkalosisIncreasesNormal, then increasesIncreases
Respiratory alkalosisIncreasesDecreasesNormal, then decreases

Reference values (arterial): pH: 7.35-7.45; pCO2: male: 35-48 mmHg, female: 32-45 mmHg; total venous bicarbonate: 22-29 mM.

Metabolic acidosis is problematic, as lower-than-normal amounts of bicarbonate are present in the blood. The pCO2 would be normal at first, but if compensation has occurred, it would decrease as the body re-establishes the proper ratio of bicarbonate and carbonic acid/CO2.

Respiratory acidosis is problematic, as excess CO2 is present in the blood. Bicarbonate levels would be normal at first, but if compensation has occurred, they would increase in an attempt to re-establish the proper ratio of bicarbonate and carbonic acid/CO2.

Alkalosis is characterised by a higher-than-normal pH. Metabolic alkalosis is problematic, as elevated pH and excess bicarbonate are present. The pCO2 would again be normal at first, but if compensation has occurred, it would increase as the body attempts to re-establish the proper ratios of bicarbonate and carbonic acid/CO2.

Respiratory alkalosis is problematic, as CO2 deficiency is present in the bloodstream. The bicarbonate concentration would be normal at first. When renal compensation occurs, however, the bicarbonate concentration in blood decreases as the kidneys attempt to re-establish the proper ratios of bicarbonate and carbonic acid/CO2 by eliminating more bicarbonate to bring the pH into the physiological range.

Section Review

Acidosis and alkalosis describe conditions in which a person’s blood is, respectively, too acidic (pH below 7.35) and too alkaline (pH above 7.45). Each of these conditions can be caused either by metabolic problems related to bicarbonate levels or by respiratory problems related to carbonic acid and CO2 levels. Several compensatory mechanisms allow the body to maintain a normal pH.

Review Questions

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Critical Thinking Questions

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Click the drop down below to review the terms learned from this chapter.

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