Respiratory alkalosis

Revision as of 17:53, 22 February 2018 by Madhu Sigdel (talk | contribs)
Jump to navigation Jump to search
<figure-inline><figure-inline><figure-inline><figure-inline><figure-inline><figure-inline><figure-inline><figure-inline><figure-inline><figure-inline></figure-inline></figure-inline></figure-inline></figure-inline></figure-inline></figure-inline></figure-inline></figure-inline></figure-inline></figure-inline> Resident
Survival
Guide
Respiratory alkalosis
ICD-10 E87.3
ICD-9 276.3
DiseasesDB 406

WikiDoc Resources for Respiratory alkalosis

Articles

Most recent articles on Respiratory alkalosis

Most cited articles on Respiratory alkalosis

Review articles on Respiratory alkalosis

Articles on Respiratory alkalosis in N Eng J Med, Lancet, BMJ

Media

Powerpoint slides on Respiratory alkalosis

Images of Respiratory alkalosis

Photos of Respiratory alkalosis

Podcasts & MP3s on Respiratory alkalosis

Videos on Respiratory alkalosis

Evidence Based Medicine

Cochrane Collaboration on Respiratory alkalosis

Bandolier on Respiratory alkalosis

TRIP on Respiratory alkalosis

Clinical Trials

Ongoing Trials on Respiratory alkalosis at Clinical Trials.gov

Trial results on Respiratory alkalosis

Clinical Trials on Respiratory alkalosis at Google

Guidelines / Policies / Govt

US National Guidelines Clearinghouse on Respiratory alkalosis

NICE Guidance on Respiratory alkalosis

NHS PRODIGY Guidance

FDA on Respiratory alkalosis

CDC on Respiratory alkalosis

Books

Books on Respiratory alkalosis

News

Respiratory alkalosis in the news

Be alerted to news on Respiratory alkalosis

News trends on Respiratory alkalosis

Commentary

Blogs on Respiratory alkalosis

Definitions

Definitions of Respiratory alkalosis

Patient Resources / Community

Patient resources on Respiratory alkalosis

Discussion groups on Respiratory alkalosis

Patient Handouts on Respiratory alkalosis

Directions to Hospitals Treating Respiratory alkalosis

Risk calculators and risk factors for Respiratory alkalosis

Healthcare Provider Resources

Symptoms of Respiratory alkalosis

Causes & Risk Factors for Respiratory alkalosis

Diagnostic studies for Respiratory alkalosis

Treatment of Respiratory alkalosis

Continuing Medical Education (CME)

CME Programs on Respiratory alkalosis

International

Respiratory alkalosis en Espanol

Respiratory alkalosis en Francais

Business

Respiratory alkalosis in the Marketplace

Patents on Respiratory alkalosis

Experimental / Informatics

List of terms related to Respiratory alkalosis

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Priyamvada Singh, M.D. [2]Madhu Sigdel M.B.B.S.[3]

Overview

Acid-base status of an organism is determined by the extracellular fluid (ECF) hydrogen ion concentration [H+] since pH is equal to minus log of [H+] i.e. pH = -log[H+]. Normal pH of human blood is 7.40 (7.35-7.45). Acidosis raises ECF [H+] thereby lowering pH whereas alkalosis lowers ECF [H+] thereby raising pH of the ECF.

Respiratory alkalosis is an acid-base disorder, primarily a decrease in partial pressure of carbon dioxide in arterial blood i.e.PaCo2 [normal PaCo2 is 40 mm Hg on average with range between 35-45mm Hg(4.7-6.0kPa)] with or without compensatory decrease in serum bicarbonate [HCO3-] (normal bicarbonate is 22-30mEq/L in arterial blood gas analysis) and pH being alkaline (normal pH of blood is 7.35-7.45). Respiratory alkalosis in almost all cases results from increased alveolar respiration (hyperventilation) leading to decrease in blood carbon dioxide concentration measured as PaCO2. This leads to decreased hydrogen ion [H+] and bicarbonate [HCO3-] concentrations. Decreased [H+] leads to increase in pH leading to alkalosis.

Pathophysiology

Production of CO2 in body tissues by intracellular metabolic process(from oxidation of fat, carbohydrate and carbon skeleton of amino acids in normal metabolic process produces carbon dioxide and water) and elimination of CO2 through lungs are in equilibrium under normal physiology. CO2 in body tissues from normal metabolic process enters blood in the tissues because its local partial pressure in tissues is greater than the partial pressure in blood flowing through the tissues due to property of gases to diffuse from high pressure to low pressure. Flowing blood transports the CO2 to the lungs, where it diffuses into the alveoli and then to the atmosphere by pulmonary ventilation. Most of tissue CO2 is brought to lungs as plasma venous bicarbonate ions.The reversible combination of CO2 with water in the red blood cells under the influence of carbonic anhydrase enzyme accounts for about 70 percent of the CO2 transported from the tissues to the lungs.

Compensation in respiratory alkalosis

compensation for respiratory alkalosis is mostly mediated through plasma buffers and proteins (eg. hemoglobin in RBC, plasma proteins) in acute stage and by kidneys in chronic compensatory stage.

Acute compensatory stage

  • Starts within minutes to hours and consists of cellular uptake of HCO3- and buffered by intracellular phosphates and proteins[1]
  • For every PaCO2 decrease of 10 mm Hg, serum bicarbonate decreases by 1-2mEq/L
  • Change in pH is unpredictable

Chronic compensatory stage

  • Renal mediated process where reduction in PaCO2 leads to decreased renal tubular H+ secretion. Within the renal tubular cells, CO2, under the influence of carbonic anhydrase enzyme, combines with H2O to form carbonic acid (H2CO3), which then dissociates into HCO3- and H+. Alkalosis inhibits carbonic anhydrase activity, resulting in reduced H+ secretion into the renal tubule. As a result, there is not enough H+ in the renal tubular fluid to react with all the filtered HCO3− from glomerular capillaries of the kidneys. Therefore, the HCO3− that cannot react with H+ is not reabsorbed and is excreted in the urine.
  • Starts after 24-36 hours and renal compensation for sustained hypocapnia is complete in 36-72 hours
  • For every PaCO2 decrease of 10 mm Hg, serum bicarbonate decreases by 5mEq/L
  • pH in chronic compensation is near normal

Classification

There are two types of respiratory alkalosis: chronic and acute.

Acute respiratory alkalosis

  • Lasting for less than 24-48 hours
  • Increased levels of carbon dioxide are "blown off" by the lungs, which are hyperventilating.
  • During acute respiratory alkalosis, the person may lose consciousness where the rate of ventilation will resume to normal.

Chronic respiratory alkalosis

  • Lasting for longer than 24-48 hours
  • For every 10 mM drop in pCO2 in blood, there is a corresponding 5 mM of bicarbonate ion drop.
  • The drop of 5 mM of bicarbonate ion is a compensation effect which reduces the alkalosis effect of the drop in pCO2 in blood. This is termed metabolic compensation.

Causes[2]

Lung and airways

Central respiratory drive

Systemic diseases

Special considerations

Symptoms

  • Symptoms of acute respiratory alkalosis are related to the decrease blood carbon dioxide levels (PaCO2) that leads to reduced cerebral blood flow resulting from vasoconstriction of cerebral vessels. Most of the symptoms arise when PaCO2 falls below 30 mm Hg and include:
    • Light-headedness, syncope
    • Confusion,
    • Seizures,
    • Peripheral and circumoral paresthesias, and cramps.
    • Chest pain and shortness of breath are seen in patients hyperventilating due to pain or anxiety.
    • Chronic respiratory alkalosis is generally well tolerated without apparent clinical symptoms
  • Signs include:
    • Tachypnea or hyperpnea
    • Carpopedal spasm due to tetany as a result of decreased levels of ionized calcium in the blood (ionized calcium are driven inside cells in exchange for hydrogen ion [H+] as compensatory mechanism to correct pH) with no fall in total serum calcium level. Alkalosis also increases protein-bound fraction of calcium reducing free calcium.
    • Respiratory patterns in respiratory alkalosis my be regular with increased rate and tidal volume OR Cheyne-Stokes type

Laboratory Findings

  • Arterial blood gas analysis(ABG):
    • It is the diagnostic test of choice for respiratory alkalosis
    • primary respiratory alkalosis has pH> 7.45, PaCO2 <35mm Hg or 4.7kPa while PaO2 is normal(>80mm Hg or 10.7kPa)
  • Serum electrolytes: Decrease in [HCO3-],[Na+], [K+] and ionized [Ca++] are seen in acute hypocapnia due to intracellular shift whereas decreased [HCO3-] and hyperphosphatemia are seen in sustained hypocapnia.[3]
  • Other laboratory test and imaging studies that may be useful in respiratory alkalosis to find out the causes includes:
    • Urine pH and urinalysis
    • CBC: elevated WBC in sepsis
    • Blood/sputum/urine C/S: for sepsis
    • EKG and ECHO: for congestive heart failure
    • Drug screening test
    • Thyroid function test: to rule out hyperthyroidism
    • Liver function test: abnormal in hepatic causes
    • pulmonary function test: to rule out chest infections
    • V/Q scan: to rule out pulmonary embolism
    • Chest X-ray: for chest infection
    • CT scan: for pulmonary embolism
    • MRI brain: to rule out CNS cause of hyperventilation

Treatment

  • Respiratory alkalosis is not a life threatening disorder, so treatment is directed at the underlying causes of the disorder.
    • patients with hyperventilation disorder (eg. anxiety, conversion disorder) are benefited from rebreathing mask.
    • High altitude sickness is treated with acetazolamide 250mg 12 hourly, Dexamethasone 4mg 6 hourly, oxygen therapy and descent to lower altitude in severe cases.
    • For critically ill patients on mechanical ventilation with respiratory alkalosis, tidal volume and respiratory rate needs to be decreased with adequate pain control.
    • Sedatives and antidepressants should not be used in cases of respiratory alkalosis.


Related Chapters

Template:WikiDoc Sources

  1. Schmoldt A, Benthe HF, Haberland G (1975). "Digitoxin metabolism by rat liver microsomes". Biochem Pharmacol. 24 (17): 1639–41. PMID https://doi.org/10.1016/j.cvsm.2016.10.005 Check |pmid= value (help).
  2. Bear RA (1986). "A clinical approach to the diagnosis of Acid-base disorders". Can Fam Physician. 32: 823–7. PMC 2327641. PMID 21267134.
  3. Krapf R, Jaeger P, Hulter HN (1992). "Chronic respiratory alkalosis induces renal PTH-resistance, hyperphosphatemia and hypocalcemia in humans". Kidney Int. 42 (3): 727–34. PMID 1405350.