Blood Gases, pH & Buffers (Acid-Base Balance) Slides

Summary

These slides cover the topic of blood gases, pH and buffer systems (acid-base balance). They include lesson objectives, chemical & physiological systems, calculations, and more. The document is a lecture summary.

Full Transcript

Blood Gases, ph
& buffer systems(Bishop text – Chapter 12)

Paul R. Nelson, M.S., MLS(ASCP)
Associate professor, Medical Lab Sciences
[email protected]
 Lesson Objectives
Describe chemical & physiological systems involved in acid/base balance,
including bicarb, phosphate, protein & hemoglobin buffer systems along with
role of kidneys & lungs
Use Henderson-Hasselbalch equation to predict pH or bicarb of sample
Define/describe & identify 4 major acid/base imbalances: metabolic acidosis &
alkalosis, respiratory acidosis & alkalosis
Explain compensation mechanisms for each acid/base imbalance
Use Henderson-Hasselbalch to determine acid/base disorder & compensatory
status
Describe O2 transport & assessment mechanisms for patient O2 status
Describe pH, pCO2, 2,3-DPG/BPG & temp affect on O2 dissociation curve shape
Describe measurement principles of pH, pCO2, pO2 & various hemoglobins
Explain clinical significance of:
pH, pCO2, pO2, bicarb, carbonic acid, base excess, O 2 saturation, fractional
oxyhemoglobin, hemoglobin oxygen (binding) capacity, oxygen content & ,
total CO2
Discuss collecting & handling samples for blood gas analysis: i.e. syringes,
anticoagulants, mixing, icing, capillary vs venous vs arterial samples
Describe methods used to measure various hemoglobins, pH & blood gas
parameters
Describe QA/QC processes, proficiency testing & delta checks to assess blood
gas result quality
Discuss reasons for discrepancies, given O2 saturation data calculated by blood
gas analyzer & measured by CO-oximeter
 ACID/BASE BALANCE
Acid: substance donating hydrogen (H+) ions when dissolved in water
Base: substance accepting H+ ions when dissolved in water

pH: represents measurement of body’s regulation of H+
aka, measurement sample acidity
pH represents negative logarithm of hydrogen ion concentration

Henderson-Hasselbach equation mathematically shows: for every
1 pH unit decrease, hydrogen ion concentration increases 10-
foldIn short, the more hydrogen ion concentration in the blood,
the lower the pH:
pH normal range: 7.35 – 7.45
Decreased pH = more hydrogen in sample (more acidic)
Increased pH = less hydrogen in sample (more basic)
 Buffer Systems:
Buffers: resist pH changes; combination of weak acid & corresponding salt
base
Buffering systems = correct combinations of acid/base to produce
desirable outcome
Bicarbonate/Carbonic Acid buffering system is a principle body pH
buffering systems

Effectiveness of a buffering system depends on pKa of environmental pH

Ka (Dissociation/Ionization Constant): describes relative
strength of acid or base; tables of known dissociation
constants exist for many acids/bases
pKa (negative log of dissociation constant): describes point at
which sample/solutions are at equilibrium (aka neutralization)
if acid is spilled, how much base (amount & concentration)
required to neutralize
 Acid/base balance:
Role of lungs & kidneys
Transport of CO2
CO2 is waste product of most aerobic metabolic
processes
CO2 easily diffuses out of tissue & into surrounding
capillary plasma/RBCs
Dissociation of carbonic acid causes concentration
gradient due to increased bicarb in RBCs
At rate determined by needs of body:
Lungs (respiratory): exchange CO2 for fresh O2
Most efficient when dissolved plasma CO2 (dCO2) = CO2 in
lungs
Kidneys (metabolic): reabsorption of needed bicarb &
excretion of acids (primarily ammonium ions & hydrogen)
 Acid/base balance:
Role of lungs & kidneys (cont’d)

Regulation of hydrogen ions (aka pH)
Body produces ~150g of H+ per day
Blood pH regulated via lungs (respiratory) &
kidneys (metabolic)
Body stores & excretes excess hydrogen to maintain
homeostasis
Extremely narrow pH Range required to sustain life: 7.35-
7.45
Acidosis: pH level below reference range (7.45)
 Regulation of H+
(cont’d)

Buffer systems: body’s 1st line of defense against extreme H+
concentration changes
Bicarb/carbonic acid buffering system important for three reasons:
1. H2CO3 dissociates into CO2 & H2O
allows CO2 to be eliminated by lungs
hydrogen to be eliminated as water by kidneys
2. Changes in CO2 concentration can speed up/slow
down breathing (respiratory)
3. HCO3− concentration can be altered by kidneys
(metabolic)
 pH: Respiratory regulation
Lungs (respiratory pathway): Blood pH affected by respiratory
ventilation
O2 inhaled/diffuses from alveoli into blood then into tissue cells
CO2 created during cellular metabolism
Diffuses into blood then alveoli & eliminated via respiratory
exhalation
Minimal H+ concentration changes between venous &
arterial circulations
 pH: metabolic regulation
Kidneys (metabolic pathway): Blood pH affected by hydrogen
elimination
Kidneys regulate acid/base balance by filtering/excreting acids & bases
Bicarb (HCO3−) filtered then reabsorbed back into blood
stream
serves as blood buffer (base) to prevent excessive blood acid
gain
 Henderson-Hasselbach Equation
Henderson-Hasselbach equation shows pH balancing relationship of
lungs & kidneys

pH is negative log of hydrogen ion concentration
pKa is pH at which equal concentrations of protonated & unprotonated
solutions exist
For blood pH this is constant at 6.1
A- is concentration of hydrogen proton acceptor aka weak base
(~bicarb)
HA is concentration of hydrogen proton donor aka weak acid
(~carbonic acid)

Short (~4 mins) clip re: Henderson-Hasselbach:
https://www.youtube.com/watch?v=ww6-jlr72Dw
 Henderson-Hasselbach

Knowing any 3 variables allows calculation of
4th
Plug in pKa: 6.1 for bicarb/carbonic acid buffer
(constant/known)
Plug in results from lab testing (see example
below)
Normal HCO3 is ~24
Normal pCO2 is ~40 - then Multiply pCO2 result by 0.03 (solubility
constant in plasma)
Ratio of Bicarb to Carbonic Acid is ~20:1
 Oxygen & carbon dioxide
Exchange
Seven conditions necessary for adequate tissue oxygenation:
1. Available atmospheric oxygen
2. Adequate ventilation
3. Gas exchange between lungs & arterial blood
4. Loading of O2 onto hemoglobin
5. Adequate hemoglobin
6. Adequate transport
7. Release of O2 to tissue

Factors influencing amount of O2 moving thru lungs, blood, tissue:
Destruction of alveoli
Pulmonary edema
Airway blockage
Inadequate blood supply
Diffusion of CO2 & O2
 Oxygen Transport
Disturbances in O2 & CO2 conditions can
result in poor tissue oxygenation (hypoxia)
pO2 (along w/ pH & pCO2) measured to
evaluate patient’s O2 status

Most O2 in arterial blood is transported to tissue via
hemoglobin:
1. Oxyhemoglobin (O2Hb): O2 reversibly bound
to hemoglobin
2. Deoxyhemoglobin (HHb): hemoglobin not
bound to O2 but capable of forming a bond
when O2 is available (aka reduced
hemoglobin)
3. Carboxyhemoglobin (COHb): hemoglobin
bound to CO
 Assessing Oxygen Status
Four parameters used to assess a patient’s
oxygen status:
1. Oxygen saturation (SO2 or 02 sat)
2. Amount of O2 dissolved in plasma (pO2)
3. Fractional (percent) oxyhemoglobin (FO2Hgb)
4. SO2 trends assessed via transcutaneous (TC) pulse
oximetry (SpO2)
 Hemoglobin/Oxygen Dissociation

O2 releases/dissociates from carrier hemoglobin
into tissues
Dissociation of O2 Oxygen from adult (A1) Hgb
in known, characteristic S-shaped curve
Dissociation curve shape & Hgb affinity for O2
affected by:
pH (Hydrogen ion activity)
PCO2 levels
Body Temp O2 dissociation curves:
A = increased affinity
2,3-Diphosphoglycerate (2,3DPG) levels B = Normal
C = Decreased affinity
 Oxygen Saturation
Measurement
O2 Saturation: ratio of hemoglobin already bound to oxygen
compared to all hemoglobin available to carry O2 (normal = 95-
100%)
Actual % oxyhemoglobin (O2Hb) determined via co-oximeter
spectrophotometer
Number of wavelengths incorporated into instrument
determines number of different hemoglobins that can be
measured (from four to hundreds)
Sources of error: faulty instrument calibration & spectral-
interfering substances
 pH, PCO2 & PO2
Measurement

Blood Gas Analyzers measure pH, PCO2 & PO2 via
electrodes
Amperometry (Clarke Electrode): amount of current flow indicates
amount of PO2
Potentiometry: change in voltage indicates analyte (PCO2, pH, etc.)
activity

Electrochemical cell: opposing electrodes immersed in
sample to conduct current
Cathode End: (1) negative electrode; (2) site to which
cations are attracted; (3) site at which reduction
occurs
Anode: (1) positive electrode; (2) site to which anions
are attracted; (3) site at which oxidation occurs
 pH, PCO2 & PO2 Measurement
(cont’d)

Measurement of PO2
PO2 (Clarke) electrodes measure amount of current
flow in circuit related to amount of O2 being reduced
at cathode
Sources of Error: buildup of protein material on
surface of membrane, bacterial contamination within
measuring chamber
Continuous measurements for PO2 are possible using
transcutaneous electrodes placed directly on skin
Measurement of pH & PCO2
Ion force measurement requires two electrodes &
voltmeter
Potential difference is related to concentration of ion
of interest by Nernst equation
 Types of Measurement Devices

Electrochemical Sensors
Macroelectrode sensors: used in blood gas instruments
since beginning of clinical measurement of blood gases
Microelectrodes: miniaturized macroelectrodes
Thick and thin film technology: sensors are tiny wires
embedded in printed circuit card that are disposable

Optical Sensors
Use fluorescent dyes, into which sample diffuses
Have been applied to indwelling blood gas systems
Blood Gas Instrument Calibration
pH & blood gas measurements are extremely sensitive to
temperature

pH electrode is calibrated with two buffer solutions

Two gas mixtures with known pCO2 and pO2 levels are used
First one used to calibrate lower end gases (mixture
is 0% O2 & 5% CO2)
Second used to calibrate upper end gases (mixture
is 20% O2 and 10% CO2)

Most instruments self-calibrating & will have alarm to indicate
any calibration error

Temperature Correction
By convention, pH, PCO2 & PO2 are all measured at
37°C
 Calculated Parameters

Directly Measured Results: pH, PCO2,
PO2, O2 sat
Calculated Results:
HCO3−: Henderson-Hasselbalch;
calculated when pH & PCO2 results
are available
H2CO3 (Carbonic acid): calculated
using solubility coefficient of CO2 in
plasma (37°C)
Total Carbon Dioxide (TCO2):
bicarbonate + dissolved CO2 + CO2
bound to proteins
Base Excess (BE): Used to quickly
assess metabolic pathway base
imbalance
Base Excess refers to the excess
amount of base (bicarb) present in
blood
Positive base excess results = excess
bicarb (suggestive of metabolic
 Quality Assurance (QA) &
Proficiency Testing (PT)
Must cover: Pre-analytic, Analytic & Post-analytic phases of testing
Preanalytic Considerations
Proper patient identification, correct labeling of specimen &
accurate info provided
Experienced, knowledgeable collection personnel
Proper collection & handling of blood gas specimens
Transport time

Analytic Considerations: QC
Commercially available liquid control samples often used
Sealed glass containers w/suitable matrix & gases of known
concentration
Split sample analysis on one device or running one sample
on two or more instruments

Post-Analytic Considerations: Result Interpretation

Participating proficiency testing program is essential for quality of
Quality Assurance
(cont’d)
 Common Sources of error

Wrong collection device (usually syringe)
Form & concentration of heparin used for
anticoagulation
Speed of syringe filling

Not maintaining strict anaerobic
environment
Introduction of air bubbles

Not mixing sample to ensure dissolution &
distribution of heparin
Long storage/waiting time between
collection & analysis
 Acid/Base Balance Disorders:
Two primary concerns: Acidosis or Alkalosis
Two subclasses each: Respiratory or Metabolic

The following regulatory mechanisms help describe what is happening
in body (clinically)
 Respiratory Acidosis
Acidosis: blood pH too low; can be caused by respiratory or metabolic
condition
Respiratory: decreased lung function
Causes: AS A COW
Airway Obstruction
Sedatives
Acute lung disease
Chronic lung disease
Opioids
Weakness of respiratory muscles

Body tries to compensate for Respiratory Acidosis
via kidneys:
Kidneys can increase rate of bicarbonate reabsorption to
increase base
Lung dysfunction is problem so kidneys must compensate
 metabolic Acidosis
(aka non-respiratory acidosis)
Non-respiratory dysfunction, usually kidney (or GI), issue
causing acidic pH

Causes: MUDPILES (high AG) & HARDASS (normal AG)
Methanol Hyperalimentation
Uremia Addison’s Disease
Diabetic ketoacidosis Renal Tubular Acidosis
Propylene glycol Diarrhea
Iron tablets & isoniazid Acetazolamide
Lactic acid Spironolactone
Ethylene glycol Saline Infusion
Salicylates

Body tries to compensate for Metabolic
Acidosis via lungs
Lungs expel more CO2 via hyperventilation
Kidney dysfunction is problem so lungs must
compensate
 Respiratory Alkalosis
Alkalosis (alkalemia): pH too high; can be caused by respiratory or
metabolic condition
Respiratory: hyperventilation; excessive elimination of CO2

Causes: PAST PH
Panic Attacks
Anxiety Attacks
Salicylates
Tumor
Pulmonary embolism
Hypoxemia

Body tries to compensate for Respiratory Alkalosis via
kidneys
Kidneys can eliminate more bicarbonate (decreased
reabsorption) to increase acid
Lung dysfunction is problem so kidneys must compensate
 metabolic Alkalosis
(aka non-respiratory alkalosis)
Metabolic dysfuntion: pH too hige; loss of hydrogen/gain in
bicarbonate

Causes: LAVA-UP
Loop Diuretics
Antacid Use
Vomiting
Aldosterone Up (increased)

Body tries to compensate for Metabolic Alkalosis via
lungs
Lungs can slow respirations (hypoventilation) to increase
acid via more CO2 in blood
Kidney dysfunction so lungs must compensate
 acid/base imbalance: 4 steps
STEP 1: Is pH outside normal range?
If yes, is it acidosis (7.45)?
If pH normal, check pCO2 & HCO3 to determine normality isn’t
compensatory mechanism

STEP 2: Respiratory or Metabolic issue?
*if pH, pCO2 & HC03 are all normal, there is no acid/base
imbalance
If pCO2 abnormal = suggests Respiratory
If HCO3 abnormal = suggests Metabolic
If Both Abnormal, use Step 3; if only 1 abnormal, skip to Step
#4

STEP 3: only Use when both PCO2 & HCO3 are abnormal
MOST abnormal parameter usually determines primary issue
(respiratory or metabolic)
Based on distance away from mean of analyte normal range

STEP 4: Is patient compensating (fully or partially) or not compensating?
Body will attempt to compensate for whatever defect is causing
acid/base imbalance
 4 Step Process
Used if any of the primary blood gas results (pH, pCO2, HCO3) are
abnormal
If all 3 primary results are normal, patient is not having an acid/base crisis
STEP 1: Acidosis or Alkalosis?
Is arterial blood pH outside of reference range?
If pH is low (< 7.35) = ACIDOSIS
If pH is high (> 7.45) = ALKALOSIS
If Normal, are pCO2 and/or HCO3 abnormal?

STEP 2: Respiratory or Metabolic?
Look at pCO2 & HCO3 results
If pCO2 is out of range = RESPIRATORY
If HCO3 is out of range = METABOLIC

Example #1 (Respiratory Acidosis) EXAMPLE #3
pH = 7.26 pH = 7.24
pCO2 = 56 pCO2 = 44
HCO3 = 24 HCO3 = 18

Example #2 (Respiratory Alkalosis) EXAMPLE #4
pH = 7.50 pH = 7.52
pCO = 30 pCO2 = 44
 4 step process
(cont’d)
STEP 3: Used when both pCO2 & HCO3 are Abnormal

If pCO & HCO are both abnormal: furthest away from 100%
2 3

is primary issue
Verify which parameter is furthest from 100%:
Divide pCO2 by 40 (reference mean)
Divide HCO3 by 25.5 (reference mean)

EXAMPLE #5: Metabolic Acidosis
pH = 7.25 (acidic)
pCO2 = 30 (abnormal) (check: 30/40 = 75.0%)
HCO3 = 15 (abnormal) (check: 15/25.5 = 58.8% furthest
away from 100%)

EXAMPLE #6: Metabolic Alkalosis
pH = 7.55 (Alkaline)
 4 step process (cont’d)

STEP 4: Is patient uncompensated, partially compensated or fully
compensated
Uncompensated: pH & 1 other parameter (pCO2 or
HCO3) abnormal
Partially Compensated: pH, PCO2 & HCO3 (all 3)
are abnormal
Compensation mechanism has kicked in but pH is still
abnormal
Fully Compensated: both PCO2 & HCO3 abnormal
but pH has normalized
Compensation mechanism has kicked in and brought pH
back within limits

Quick Reference Charts:
 EXAMPLE #7
Patient Results:
pH = 7.33
pCO2 = 60
HCO3 = 30

Step #1: is patient normal, acidic or alkaline?
Step #2: is patient in metabolic or respiratory distress?
If PCO2 = Respiratory
HCO3 = Metabolic
If Both = Go To Step 3
Step #3: If both PCO2 & HCO3 are abnormal, which is furthest from
100%?
If PCO2 = Respiratory (do the math: 60/40 = 150.0%)
HCO3 = Metabolic (do the math: 30/25.5 = 117.6%)
Step #4: is patient uncompensated, partially compensated or fully
compensated
Are both PCO2 & HCO3 abnormal?
If No = Uncompensated
If Yes, has pH normalized yet?
If No = Partially Compensated
If Yes = Fully Compensated
 EXAMPLE #8
Patient Results:
pH = 7.52
pCO2 = 28
HCO3 = 21

Step #1: pH is alkaline
Step #2: Both pCO2 & HCO3 are abnormal (low)
Step #3: pCO2 is furthest from 100 % of mean reference range
pCO2: 28/40 = 70.3% ; HCO3: 21/25.5 = 82.3%

Step #4: pH has not normalized but HCO3 is abnormal due to
attempted compensation
 EXAMPLE #9
Patient Results:
pH = 7.39
pCO2 = 25
HCO3 = 15

Answer: Fully Compensated Metabolic Acidosis
Step #1: pH is normal
Step #2: Both pCO2 & HCO3 are abnormal/critical low (pt in crisis)
Step #3: HCO3 is furthest from 100% of it’s reference mean
(metabolic)
Step #4: pH has normalized (fully compensated)
Difficult to distinguish between Fully Compensated Acidosis/Alkalosis
Quick Rule: use whichever side of pH mean patient result lands
In this example, pH is normal (7.39) but below pH mean (7.40); so slightly
acidic
Common sense check: since HCO3 is “more abnormal” lack of HCO3 is likely
primary concern
If not enough base, blood gets acidic; lungs compensate via hyperventilation to
slowly lower PCO2
 EXAMPLE #10
Patient Results:
pH = 7.38
pCO2 = 42
HCO3 = 26

Step #1: pH is normal
Step #2: pCO2 & HCO3 both normal
Step #3: N/A
Step #4: N/A

Answer: Normal Patient Not in Acid/Base Crisis
 Questions ???

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