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Acid base balance (updated in 2020)
1. Acid Base Balance
(Part I)
Dr. Ifat Ara Begum
Associate Professor
Department of Biochemistry
Dhaka Medical College, Dhaka
14/10/2020
2. Learning objectives
Acid: Definition, types, sources
Base : Definition, types, sources
pH : Definition, normal blood pH, maintenance of static blood pH
Acid base disorders : Types
2
3. Proton (H
+
) donor in aqueous
solution
pH <7
Produces H+ when dissolved in water
May be charged particle [NH4
+,
H2PO4
-] or may be without charge
[HCl]
Types: Strong acid , Weak acid
Proton (H+) acceptor in aqueous
solution
pH >7
Produces OH- when dissolved in water
May be charged particle [Cl-, HCO3
-]
or may be without charge [NH3]
Types: Strong base , Weak base
Acid Base
4.
5. Rapidly & completely ionized in solution
into H+ & its conjugate base.
Degree of dissociation & dissociation
constant is high
pK value: Low
As conjugate base shows less affinity to H+,
rapid and complete ionization to proton
occurs. So, conjugate bases of strong acids
are weak.
Example: All inorganic acids except H2CO3
Slowly & partially ionized in solution into
H+ & its conjugate base.
Degree of dissociation & dissociation
constant is low
pK value: High
As conjugate base shows strong affinity
to H+, slow and partial ionization to
proton occurs. So, conjugate bases of
weak acids are strong.
Example: All organic acids and H2CO3
Strong Acid Weak Acid
6. Have greater tendency to accept proton.
Bind rapidly & strongly with proton, so,
remove them quickly from solution
Conjugate acid: weak
Example: HCO3
- , OH-
Have low tendency to accept proton.
Bind slowly & weakly with proton, so,
remove them slowly from solution
Conjugate acid: strong
Example: Cl- , SO4
-2
Strong Base Weak Base
7. Proton is the hydrogen atom with its electron removed
7
9. 9
Conjugate base of acid
The remaining anionic part of an acid
after removal of proton from the acid
In strong acid, it is weak & vice versa
Conjugate acid of base
It is the acid formed by a base after
accepting proton
Conjugate acid of a strong base is weak
& vice versa
10. 10
Strength of an acid / base is defined in terms of the tendency
to donate (or accept) the hydrogen ion to (from) the solvent
(i.e. water in biological systems)
11. Sources of Acid / Base in our body
Endogenous source:
Produced at cellular level during metabolism
Exogenous source:
Potentially acidic / basic substances get entry in to the body fluid through
enteral / parenteral route
i.e. via
Foods rich in acid (meat)
Ingestion of acids (salicylic acid)
Intravenous infusion
11
12. 12
Sources of Volatile acid:
15 – 20 mol / day
Oxidation of :
Glucose
FA
AA
Sources of NVA:
230 mmol / day
Oxidation of :
Basic AA (His, Arg, Lys)
S - containing AA (Cys, Met)
PO4 containing substances
Sources of Base (nonvolatile):
160 mmol / day
Oxidation of Acidic AA (Asp, Glu)
Metabolism of dietary organic anions like citrate, acetate etc
13. ‘Our body is net acid producer’- Justify
13
NVA & base neutralize each other at
one to one ratio
So, even after neutralization,
70 mmol/D NVA is left behind
(230-160 = 70)
This 70 mmol/D of NVA, along with
15-20 mol/D of volatile acid makes the
body environment acidic
A normal 70 kg adult individual at
normal metabolic status produces:
Volatile acid: 15 – 20 mol / day
Nonvolatile acid: 230 mmol / day
Base (nonvolatile): 160 mmol / day
14. Metabolic acid or base production depends on:
14
Insulin status: Insulin deficiency causes acid production
Blood flow to tissues: Decreased blood flow causes acid
production
Oxygen supply to tissues: Hypoxia causes acid production
Dietary habit: Protein produces more acid, vegetables produce
less acid , fruits produce more base
15. Routes for excretion of acid / base from body
15
Pulmonary / Respiratory route Renal route
For excretion of volatile acids only For excretion of NVA & bases
(nonvolatile)
High capacity system
(disposes huge acid load)
Low capacity system
(disposes moderate acid load)
Unidirectional
(Excrete only acid)
Bidirectional
(Excrete both acid & base)
On complete failure for few minutes, it
reduces pH grossly
On complete failure for few minutes, no
effect on pH at all
16. State of H+ conc. of a solution:
Acidity of a solution
It is directly proportional to the acid
content & indirectly proportional to the
base / alkali content of the solution.
It can be measured in :
Arithmetic scale: Has a definite absolute unit and measures acidity (H+ conc. ) by
exponential expression (10-7 mol/L) or by decimal expression (0.001mol/L)
Logarithmic scale (pH scale): Has no unit, measures acidity by pH
In logarithmic scale (pH) In arithmetic scale (H+concentration
in nmol/L)
7.35 45
7.45 35
21. How pH can be determined?
Instrumentally by pH meter
Using H-H Equation (From serum HCO3 conc. &
PCO2 )
21
22. Supports optimum enzyme activity for
smooth running of metabolism
Concerned with O2 transport & chemical
control of respiration
Maintains:
The native molecular form & structural
conformation of biomolecules (esp. protein)
at which they are functionally active
Internal environment (ECF) & cellular
viability by regulating proper electrolyte
distribution in ECF via Na+ - K+ pump
Altered :
Enzyme activity
Membrane permeability
CNS activity
Electrolyte distribution
Increased myocardial irritability
Decreased cellular viability
Organ dysfunction
Importance of normal body pH
Why Life threatens beyond
clinically safe range (7.3 – 7.5) of
pH?
23. Here are some Important Effects of pH change in body
24.
25. H+ ions are very reactive
cation
Proteins are anions at body pH
H+ ions at higher
concentrations can bind
strongly to negatively charged
proteins, including enzymes,
and impair their activity and
hence the cell function.
26.
27. How pH is regulated?
27
First Line Defense
Chemical buffer system / Body buffer system: It acts within second to minutes
Pulmonary system: It acts within minutes to hours by regulating CO2 content
in blood
Second line Defense
Renal system: It acts within hours to days by regulating serum bicarbonate
and excretion of acid
28. Buffer
A mixture of weak acid & its conjugate base or a mixture of weak acid & its
salt with strong base
that can accept / release H+ in a solution
to resist marked changes in H+ conc. or pH of that solution
despite the addition of moderate amount of acid / base to the solution.
28
Principle of buffer action:
Conversion of strong acid in to weak acid
Conversion of strong base in to weak base
30. Body
Compartment
Buffer system
(In order of importance)
RBC Hemoglobin, Phosphate, Bicarbonate
Plasma/ ECF Bicarbonate, Phosphate, Protein
ICF Protein, Bicarbonate, Phosphate
Kidney Ammonia, Phosphate, Bicarbonate
Bone Bone buffer
31. Most important / effective buffer: Bicarbonate buffer system
31
Principal ECF buffer
At normal body pH , plasma
bicarbonate (Base) conc. is 24
mmol/L, carbonic acid (Acid)
conc. is 1.2 mmol/L with base to
acid ratio 20:1
Total buffer conc. is about 25
mmol/L
32. Advantage of Bicarbonate buffer system
32
Most effective buffer in our body against all bases and all acids except carbonic acid,
because, it is an open end system
i.e. components of this buffer system can independently be regulated by respiratory
system (carbonic acid) & renal system (bicarbonate)
Works both in ICF (36% of buffering activity) & ECF (86% of buffering activity)
(60% of total buffering activity)
Works in cooperation with Hb buffer system that increases its buffering efficiency
Base conc. is more than acid conc. which makes it more efficient to encounter the
acid load of the body (Because, our body is net acid producer)
33. Disadvantage of Bicarbonate buffer system
33
Weak buffer because of its low pK value (6.1), which is far
below the normal body pH.
(Protein and Phosphate buffer is stronger)
Cant buffer carbonic acid , so can not operate in respiratory
acid base disorders
34. Bone Buffer
Alkaline calcium phosphate salt of bone
deposited in the form of Hydroxyapatite
Crystal (HAC)
Action: Delayed, needs hours to days
Buffering capacity: Very high
No role in acute acidosis
In CRF, where chronic acidosis occurs ,
classic body buffers frequently fails to buffer
all the retained acid. So, bone buffer comes in
action at the cost of bone demineralization.
Importance of bone buffer:
Can prevent the dev. of acidosis in
mild/moderate CRF
Its activity in CRF leads to
osteoporosis of bone with resultant
hypercalcemia & calciuria
Hypercalcemia can predispose to
dev. of renal stone (as calcium
oxalate/ phosphate)
35. All buffers are related to body pH by the principle of
Henderson- Hasselbalch Equation
35
36. When principle of Henderson- Hasselbalch Equation applied
to Bicarbonate buffer system
36
Since direct measurement of
serum H2CO3 concentration is
difficult, it is frequently calculated
out in this way.
0.03 mmol / L / mm Hg is the
solubility coefficient of CO2 in
water.
This means, serum H2CO3 conc.
will increase / decrease by 0.03
mmol / L for 1 mm Hg rise / fall in
PCO2
PCO2 dCO2 H2CO3 HCO3
- + H+
PCO2 in plasma determines the dissolved CO2 (dCO2 )
content which later on gives rise to H2CO3
40. Types of ABD
Acidosis: A condition in which the blood has too much acid (or too little
base), resulting in a decrease in blood pH
Alkalosis: A condition in which the blood has too much base (or too little
acid), resulting in an increase in blood pH
41.
42.
43. Abnormality of both HCO3
- and PCO2 simultaneously: Complex ABD
(Clinically, existence of >1 simple ABD)
43
Abnormality of either HCO3
- or PCO2 , keeping 2nd component
normal: Simple ABD
49. Metabolic acidosis: A primary
disorder that causes a decrease in
the serum bicarbonate and
lowers the blood pH.
Metabolic alkalosis: A primary
disorder that causes an increase
in the serum bicarbonate and
raises the blood pH.
Respiratory acidosis: A primary
disorder that leads to an increased
PaCO2 and lowers the blood pH.
Respiratory alkalosis: A primary
disorder process that leads to a
decreased PaCO2 and raises the blood
pH.
50. Types of Complex ABD
Type of complex ABD Features Example
Double Face Types Combination of 2 disorders M.Acidosis + R. Acidosis
M. Acidosis + R. Alkalosis
M. Alkalosis + R. Acidosis
M. Alkalosis + R. Alkalosis
Triple Face Types Combination of 3 disorders M.Acidosis + M. Alkalosis + R.
Acidosis
M.Acidosis + M. Alkalosis + R.
Alkalosis
51. What are the common parameters to check ABD?
pH
PCO2
Serum HCO3
- concentration
Plasma Anion gap
Base excess
52. Normal Acid Base Composition of Arterial Blood
(ABG analysis)
pH PO2
(mm of
Hg)
O2 saturation
(%)
PCO2 (mm of Hg) HCO3 conc.
(mmol/L)
7.35 -
7.45
85 - 100 80-100
(>95%)
35 - 45 22-28
Plasma Anion gap: 8 – 16 mEq/L
Base excess : ± 2 mmol/L
53. NICE TO KNOW
Acidemia: A low blood pH (less than 7.35)
Alkalemia: A high blood pH (greater than 7.45)
Hypocapnia: A low PaCO2 (less than 35 mm Hg)
Hypercapnia: A high PaCO2 (greater than 45 mm
Hg)
55. Anion gap = UA – UC
UA: Plasma protein, phosphate,
sulphate, lactate, keto acid anions,
other organic acid anions
UC: Calcium, magnesium, gamma-
globulin
56. Normal range: 8 – 16 mEq/L
[K level is ignored since plasma K+
concentration doesn’t vary that
much]
Importance of AG:
It helps to differentiate the causes
of metabolic acidosis
It helps to determine the nature of
metabolic acidosis (simple /
complex)
57. Causes of Increased plasma AG
(remember, AG = UA-UC)
a) Any cause of increased UA:
Ketoacidosis
Lactic acidosis
Renal failure
Poisoning by alcohol, salicylates etc
Alkalosis (as part of buffering activity
of albumin) , etc
b) Any cause of decreased UC:
Hypocalcemia
Hypomagnesaemia
Hypo gamma- globulinemia
Causes of Decreased plasma AG
(remember, AG = UA-UC)
a) Any cause of decreased UA:
Hypoalbuminemia
b) Any cause of increased UC:
Hypercalcemia
Hypermagnesemia
Hyper gamma- globulinemia
58. Type of Metabolic acidosis based on Anion gap
Types of metabolic acidosis
based on AG
Causes Comments
High AG type / Normochloremic type RF, Lactic acidosis,
Ketoacidosis,
Poisoning/
Intoxication
Here serum Cl- remains normal.
AG increases in same proportion as
to the fall of HCO3-
Normal AG type / hyperchloremic type Diarrhoea, Renal
Tubular Acidosis
Here serum Cl- increases in same
proportion as to the fall of HCO3-
59. Base Excess
Difference between present /actual
bicarbonate concentration of an individual
and the standard bicarbonate concentration
Base Excess = [HCO3
-] p – [HCO3
-]std
Positive BE: High plasma HCO3
- conc. which
is found in metabolic alkalosis & respiratory
acidosis
Negative BE: Low plasma HCO3
- conc. which
is found in metabolic acidosis & respiratory
alkalosis
60. Standard plasma bicarbonate concentration:
It is the plasma bicarbonate concentration of an individual of an
individual at:
Body temperature 37 degree C
Arterial PCO2 at 40 mm Hg
Hb conc. normal 14-16 g/dl
Oxygen saturation of Hb normal >95%
Symbolized as [HCO3
-]std
24 mmol / L
61. Related term: Bicarbonate space
The apparent space of bicarbonate distribution within the body fluid.
Anatomically it is equivalent to ECF volume.
At normal serum bicarbonate level (24 mmol/L), bicarbonate space is about 30-50% of
body weight.
Inverse relationship with serum bicarbonate level.
Formula for calculation:
HCO3 space = (0.36+ 2.44 / HCO3
- concentration) x Body weight
During alkali therapy by NaHCO3 in metabolic acidosis, it is used to calculate amount of
NaHCO3 to be infused in a patient
Amount of NaHCO3 = (BE X Bicarbonate space) mmol
62. PO2
The PO2 reflects the amount of oxygen gas dissolved
in the blood.
It primarily measures the effectiveness of the lungs
in pulling oxygen into the blood stream from the
atmosphere
i.e. it provides a good index of lung function
63. Events of ABD According to Time Course
Primary event / Primary defect
Buffering by ICF & ECF buffers
Compensation / Secondary event
Correction / Repair
65. Secondary Event/ Compensation:
It follows primary event
Proportionate change in the unaffected component (PCO2 or serum HCO3
- )
in direction with the change of primary affected component
Objective is to keep the base to acid ratio near normal (20:1) so that pH
comes to near normal but still in the direction of primary disorder
100% correction / overcorrection does not occur
If underlying problem is metabolic, hyper/hypo ventilation may help , that
means, respiratory compensation
If problem is respiratory, renal mechanisms can bring about metabolic
compensation
66.
67. Simple ABD Primary
event /
Primary
defect
Unaffected
component
Secondary
event /
compensation
Mechanism of
compensation
pH after
compensation
Metabolic
Acidosis
↓ HCO3
- PCO2 ↓ in PCO2 Hyperventilation Near normal
Metabolic
Alkalosis
↑ HCO3
- PCO2 ↑ in PCO2 Hypoventilation Near normal
Respiratory
Acidosis
↑ PCO2 HCO3
-
↑ in HCO3
- Renal HCO3
-
Generation in CD
Near normal
Respiratory
Alkalosis
↓ PCO2 HCO3
-
↓ in HCO3
- Renal HCO3
-
Excretion
Near normal
68. Correction / Repair:
At the end of compensation, near normal pH is attained but plasma HCO3
concentration remains grossly abnormal which persists if compensatory drive
continues
Removal of cause of ABD by appropriate treatment turns away the system
from compensatory drive
Now normalization of plasma HCO3 concentration will be done through
renal activity
So, the ultimate aim of correction: To normalize plasma HCO3 to make
acid base status normal
69. Simple ABD Renal activity to normalize HCO3
-conc
Metabolic Acidosis Excretion of acidic urine
Generation of new HCO3
- in CD
(Role of ammonia and phosphate buffer)
Metabolic Alkalosis Excretion of alkaline urine
Inhibition of HCO3
- reabs. from PCT to allow its excretion
Respiratory Acidosis Treatment of hypercapnia
Inhibition of HCO3
- reabs. from PCT to allow renal HCO3
- excretion
Respiratory Alkalosis Treatment of hypocapnia
Increased renal HCO3
- reabs. from PCT
72. Lab diagnosis M. Acidosis M. Alkalosis R. Acidosis R. Alkalosis
pH Low High Low High
PCO2 Low High High Low
Plasma HCO3 Low High High Low
Plasma Anion Gap High / Normal Modestly raised Usually normal Usually normal
Plasma Cl- High / Normal Low usually
Base Excess - ve +ve +ve -ve
Serum K+ High usually Low usually High usually Low usually
Other Findings &
findings related to
cause
e.g. If RF: High S
/ Creatinine etc
73. Clinical types of metabolic alkalosis according to urinary chloride level
Chloride / saline responsive type:
Spot urinary chloride: <10 mmol/L
Responds to infusion of normal
saline
Causes:
GIT cause (vomiting, NG suction)
Diuretic abuse (loop diuretics &
thiazide)
Exogenous alkali administration, etc
Chloride / saline resistant type:
Spot urinary chloride: >10 mmol/L
Do not respond to infusion of
normal saline
Causes:
Hyperaldosteronism
Chronic hypokalemia
Cushing syndrome etc
74. Paradoxic Aciduria
Acidic urine excretion by an individual in spite of the presence of metabolic
alkalosis
Happens in individual with coexisting hypokalemia & metabolic alkalosis
In metabolic alkalosis, kidney is supposed to excrete alkaline urine to
correct the condition.
But due to hypokalemia, collecting duct is forced to reabsorb sodium in
exchange of H+ excretion, so urine becomes acidic