ABG INTERPRETATION DR BINOD KUMAR SINGH

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Presentation transcript:

ABG INTERPRETATION DR BINOD KUMAR SINGH Associate Professor, PMCH, Patna CIAP Executive board member- 2015 NNF State president,Bihar- 2014 IAP State secretary,Bihar-2010-2011 NNF State secretary,Bihar-2008-2009 - Consultant Neonatologist & Pediatrician Shiv Shishu Hospital :K-208, P.C Colony.Hanuman Nagar, Patna – 800020 Web site : www.shivshishuhospital.com

ABG Interpretation First, does the patient have an acidosis or an alkalosis Second, what is the primary problem – metabolic or respiratory Third, is there any compensation by the patient – respiratory compensation is immediate while renal compensation takes time

ABG Interpretation It would be extremely unusual for either the respiratory or renal system to overcompensate The pH determines the primary problem After determining the primary problem and compensatory acid/base balance, always evaluate the effectiveness of oxygenation

Normal Values pH - 7.35 to 7.45 paCO2- 36 to 44 mm Hg HCO3 -22 to 26 meq/L

Abnormal Values pH < 7.35 Acidosis (metabolic and/or respiratory) Alkalosis (metabolic and/or respiratory) paCO2 > 44 mm Hg Respiratory acidosis (alveolar hypoventilation) paCO2 < 36 mm Hg Respiratory alkalosis (alveolar hyperventilation) HCO3 < 22 meq/L Metabolic acidosis HCO3 > 26 meq/L Metabolic alkalosis

Putting It Together - Respiratory So paCO2 > 44 with a pH < 7.35 represents a respiratory acidosis paCO2 < 36 with a pH > 7.45 represents a respiratory alkalosis For a primary respiratory problem, pH and paCO2 move in the opposite direction For each deviation in paCO2 of 10 mm Hg in either direction, 0. 08 pH units change in the opposite direction

Putting It Together - Metabolic And HCO3 < 22 with a pH < 7.35 represents a metabolic acidosis HCO3 > 26 with a pH > 7.45 represents a metabolic alkalosis For a primary metabolic problem, pH and HCO3 are in the same direction, and paCO2 is also in the same direction

Compensation The body’s attempt to return the acid/base status to normal (i.e. pH closer to 7.4) Primary Problem Compensation respiratory acidosis metabolic alkalosis respiratory alkalosis metabolic acidosis metabolic acidosis respiratory alkalosis metabolic alkalosis respiratory acidosis

REMEMBER BY HEART CO2 IS A RESPIRATORY ACID Ph and HCO3- Move in same direction. pH and PCO2- Move in opposite direction. HCO3 and PCO2- Move in same direction-simple disorder. HCO3 and PCO2- Move in opposite direction-mixed disorder.

Expected Compensation Respiratory acidosis Acute – the pH decreases 0.08 units for every 10 mm Hg increase in paCO2; HCO3 1 mEq/liter per 10 mm Hg paCO2 Chronic – the pH decreases 0.03 units for every 10 mm Hg increase in paCO2; HCO3 4 mEq/liter per 10 mm Hg paCO2

Expected Compensation Respiratory alkalosis Acute – the pH increases 0.08 units for every 10 mm Hg decrease in paCO2; HCO3 2 mEq/liter per 10 mm Hg paCO2 Chronic - the pH increases 0.03 units for every 10 mm Hg decrease in paCO2; HCO3 4 mEq/liter per 10 mm Hg paCO2

Expected Compensation Metabolic acidosis paCO2 = 1.5(HCO3) + 8 (2)-winter’s formula paCO2 1-1.5 per 1 mEq/liter HCO3 Metabolic alkalosis paCO2 = 0.7(HCO3) + 20 (1.5) paCO2 0.5-1.0 per 1 mEq/liter HCO3

Classification of primary acid-base disturbances and compensation Acceptable ventilatory and metabolic acid-base status Respiratory acidosis (alveolar hypoventilation) - acute, chronic Respiratory alkalosis (alveolar hyperventilation) - acute, chronic Metabolic acidosis – uncompensated, compensated Metabolic alkalosis – uncompensated, partially compensated

Acute Respiratory Acidosis paCO2 is elevated and pH is acidotic The decrease in pH is accounted for entirely by the increase in paCO2 Bicarbonate and base excess will be in the normal range because the kidneys have not had adequate time to establish effective compensatory mechanisms

Acute Respiratory Acidosis Causes Respiratory pathophysiology - airway obstruction, severe pneumonia, chest trauma/pneumothorax Acute drug intoxication (narcotics, sedatives) Residual neuromuscular blockade CNS disease (head trauma)

Chronic Respiratory Acidosis paCO2 is elevated with a pH in the acceptable range Renal mechanisms increase the excretion of H+ within 24 hours and may correct the resulting acidosis caused by chronic retention of CO2 to a certain extent

Chronic Respiratory Acidosis Causes Chronic lung disease (BPD, COPD) Neuromuscular disease Extreme obesity Chest wall deformity

Acute Respiratory Alkalosis paCO2 is low and the pH is alkalotic The increase in pH is accounted for entirely by the decrease in paCO2 Bicarbonate and base excess will be in the normal range because the kidneys have not had sufficient time to establish effective compensatory mechanisms

Respiratory Alkalosis Causes Pain Anxiety Hypoxemia Restrictive lung disease Severe congestive heart failure Pulmonary emboli Drugs Sepsis Fever Thyrotoxicosis Pregnancy Overaggressive mechanical ventilation Hepatic failure

Uncompensated Metabolic Acidosis Normal paCO2, low HCO3, and a pH less than 7.30 Occurs as a result of increased production of acids and/or failure to eliminate these acids Respiratory system is not compensating by increasing alveolar ventilation (hyperventilation)

Compensated Metabolic Acidosis paCO2 less than 30, low HCO3, with a pH of 7.3-7.4 Patients with chronic metabolic acidosis are unable to hyperventilate sufficiently to lower paCO2 for complete compensation to 7.4

Elevated AG Metabolic Acidosis Causes Ketoacidosis - diabetic, alcoholic, starvation Lactic acidosis - hypoxia, shock, sepsis, seizures Toxic ingestion - methanol, ethylene glycol, ethanol, isopropyl alcohol, paraldehyde, toluene Renal failure - uremia

Normal AG Metabolic Acidosis Causes Renal tubular acidosis Post respiratory alkalosis Hypoaldosteronism Potassium sparing diuretics Pancreatic loss of bicarbonate Diarrhoea Carbonic anhydrase inhibitors Acid administration (HCl, NH4Cl, arginine HCl) Sulfamylon Cholestyramine Ureteral diversions Fall in HCO3 matched by equal rise in Cl, with no overall change in AG – hyperchloremic metabolic acidosis Sulfamylon – mafenide acetate, used for burns, inhibits carbonic anhydrase Cholestyramine – Questran, cholesterol lowering agent, chloride form of anion exchange resin, produces hyperchloremic acidosis

Effectiveness of Oxygenation Further evaluation of the arterial blood gas requires assessment of the effectiveness of oxygenation of the blood Hypoxemia – decreased oxygen content of blood - paO2 less than 60 mm Hg and the saturation is less than 90% Hypoxia – inadequate amount of oxygen available to or used by tissues for metabolic needs

Mechanisms of Hypoxemia Inadequate inspiratory partial pressure of oxygen Hypoventilation Right to left shunt Ventilation-perfusion mismatch Incomplete diffusion equilibrium

Assessment of Gas Exchange Alveolar-arterial O2 tension difference A-a gradient PAO2-PaO2 PAO2 = FiO2(BP - PH2O) - PaCO2/RQ* Arterial-Alveolar O2 tension ratio PaO2/PAO2 Arterial-Inspired O2 ratio PaO2/FIO2 * Respiratary quotient= 0.8

Assessment of Gas Exchange A-a DO2={(FIO2)(760-47)-(1.25)(PaCO2)}-PaO2 Normal A-a gradient -10-20 mm Hg Increased A-a gradient with hypoxemia- oxygenation failure /V-Q mismatch/lung disorder Normal A a gradient with hypoxemia- ventilation failure/hypoventilation

Assessment of Gas Exchange ABG A-a grad PaO2 PaCO2 RA 100% Low FIO2   N* N Alveolar hypoventilation   N N Altered gas exchange Regional V/Q mismatch  /N/  N/ Intrapulmonary R to L shunt  N/   Impaired diffusion  N/  N Anatomical R to L shunt (intrapulmonary or intracardiac)  N/   * N=normal

INDICATION FOR ECMO IF iNO VENTILATION INCLUDING HFO VENTILATION UNABLE TO SUSTAIN LIFE IF AO2-aO2 GRADIENT OF MORE THAN 600 mmHg FOR 6 TO 12 hrs VENTILATION INDEX= [ (RR * PIP * paCO2 ) / 1000 ] , of more than 90 for 4 hr OXYGENATION INDEX= (MAP * FiO2) Post-ductal paO2 , of more than 40 in two ABGs at 1 hr apart

ABG REPORT - SHIV SHISHU HOSPITAL PATNA DATE/TIME 27:07:2011 12:12 SAMPLE No- 5388 Pat ID B N 5 Sample type arterial blood BARO- 747.2mm Hg Temp- 37.0 C A/F FETAL PO2 82.5 mmHg(80.0-100.0 PCO2 36 mmHg(-)(35.0-45.0) pH 7.393 (7.350-7.450) Na 143.1 mmol/L(135.0-148.0) Cl 104.1 mmol/L(98.0-107.0) Ica 1.267 mmol/L(1.120-1.320) K 3.74 mmol/L(3.50-4.50) Hct 49.7 % (35.0-50.0) BE -3.6 mmol/L BEecf -4.5 mmol/L CHCO3st 23 mmol/L P50 21.5 mmHg ctO2 20.7 vol%

ABG REPORT- SHIV SHISHU HOSPITAL PATNA DATE/TIME 27:07:2011 12:17 SAMPLE No- 5389 Pat ID B N 15 Sample type arterial Blood BARO- 747.0mm Hg Temp- 37.0 C A/F FETAL PO2 153.2 mmHg(+)(80.0-100.0) PCO2 59.3 mmHg(+)(35.0-45.0) pH 7.262 (7.350-7.450) Na 136.3 mmol/L(135.0-148.0) Cl 99.4 mmol/L(98.0-107.0) Ica 0.977 mmol/L(--)(1.120-1.320) K 4.38 mmol/L(3.50-4.50) Hct 38.4 % (35.0-50.0) BE -2.1 mmol/L BEecf -0.9 mmol/L CHCO3st 22.1 mmol/L P50 21.5 mmHg ctO2 21.2 vol%

ABG REPORT-S SHIV SHISHU HOSPITAL PATNA DATE/TIME 27:07:2011 11:08 SAMPLE No- 5386 Pat ID B N 3 Sample type arterial Blood BARO- 747.2mm Hg Temp- 37.0 C A/F FETAL PO2 57.5 mmHg(--)(80.0-100.0) PCO2 26.6 mmHg(-)(35.0-45.0) pH 7.482 (+) (7.350-7.450) Na 139.6 mmol/L(135.0-148.0) Cl 101.0 mmol/L(98.0-107.0) Ica 1.006 mmol/L(--)(1.120-1.320) K 3.41 mmol/L(3.50-4.50) Hct 57.3 %(+) (35.0-50.0) BE -2.3 mmol/L BEecf -4.0 mmol/L CHCO3st 22.4 mmol/L P50 21.5 mmHg ctO2 20.2 vol%

ABG REPORT- SHIV SHISHU HOSPITAL PATNA DATE/TIME 27:07:2011 20:16 SAMPLE No- 5324 Pat ID B N 5 Sample type arterial Blood BARO- 740.4mm Hg Temp- 37.0 C A/F FETAL PO2 52.6 mmHg(--)(80.0-100.0) PCO2 24.6 mmHg(-)(35.0-45.0) pH 7.255 (-) (7.350-7.450) Na 134.1 mmol/L(135.0-148.0) Cl 98.7 mmol/L(98.0-107.0) Ica 1.064 mmol/L(--)(1.120-1.320) K 3.95 mmol/L(3.50-4.50) Hct 56.8 %(+) (35.0-50.0) BE -14.5 mmol/L BEecf -16.5 mmol/L CHCO3st 13.2 mmol/L P50 21.5 mmHg ctO2 18.7 vol%

Summary First, does the patient have an acidosis or an alkalosis Look at the pH Second, what is the primary problem – metabolic or respiratory Look at the pCO2 If the pCO2 change is in the opposite direction of the pH change, the primary problem is respiratory

Summary Third, is there any compensation by the patient - do the calculations For a primary respiratory problem, is the pH change completely accounted for by the change in pCO2 if yes, then there is no metabolic compensation if not, then there is either partial compensation or concomitant metabolic problem

Summary For a metabolic problem, calculate the expected pCO2 if equal to calculated, then there is appropriate respiratory compensation if higher than calculated, there is concomitant respiratory acidosis if lower than calculated, there is concomitant respiratory alkalosis

Summary Next, don’t forget to look at the effectiveness of oxygenation, (and look at the patient) your patient may have a significantly increased work of breathing in order to maintain a “normal” blood gas metabolic acidosis with a concomitant respiratory acidosis is concerning