Acid And Base Concepts PDF

Summary

This document discusses acid-base concepts, definitions, and calculations. It details the acid-base balance regulation in the human body and includes practice questions on the topic.

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ACID AND BASE CONCEPTS

Dr NAVEEN KUMAR
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 Learning Objectives

Unit-2: Acid and Base Concepts

2.1 The acid-base balance concept

2.2 Arrhenius definition

2.3 Acid–base equilibrium

2.4 Henderson-Hasselbalch equation
2
 Arrhenius definition of Acids & Bases
Acids- releases proton in water (proton donor).
HA H+ + A-
Acid Proton Conjugate base

Base- accepts proton in water (proton acceptor) or releases hydroxyl ions
(OH-) in water.
BOH OH- + B+
Base
Hydroxyl ion Conjugate acid
Each acid has a characteristic tendency to lose its proton(H +) in an
aqueous solution.

The stronger the acid, the greater its tendency to lose its proton(H +) but the
weak acids release their protons slowly.
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Strong acids:
A strong acid is an acid that dissociates completely into its ions in an aqueous
solution or water.
Eg: HCl, H2SO4, HNO3 (Inorganic acids)
Weak acids:
A weak acid is an acid that partially dissociates into its ions in an aqueous
solution or water.
Eg:
Inorganic acids: Formic acid (HCOOH), Acetic acid (CH3COOH), Oxalic
acid (C2H2O4), Benzoic acid (C6H5COOH)

Organic acids: Lactic acid, Phosphoric acid, Carbonic acid and Citric acid.
Weak acids are common in biological systems and produced during metabolic
reactions.
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Strong bases:
Strong bases can be defined as basic substances that can be completely
dissociate into their ions when dissolved in solutions.

Eg: NaOH, KOH, Ba(OH2)

Weak bases:
Weak bases can be defined as basic substances that do not completely
dissociate into their ions when dissolved in solutions.

Eg: Amines, NH4+ , Aniline, Pyridine

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 Acids Produced In The Human Body
Carbonic acid - Oxidation of carbon compounds

Sulphuric acid - Oxidation of sulphur containing amino acids.

Phosphoric acid- metabolism of dietary phosphoproteins , nucleoproteins, phosphatides.

Organic acid- oxidation of carbohydrates, fats and proteins.
e.g. pyruvic acid ,lactic acid , acetoacetic acid etc.

Iatrogenic : - certain medicine like NH4Cl, mandelic acid etc.

NOTE:DIET RICH IN ANIMAL PROTEIN RESULTS IN MORE ACID PRODUCTION.

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 Acidic Substances of Human body:
Carbonic acid(H2CO3)
Phosphoric acid( H3PO4)
Sulphuric acid (H2SO4)
Organic Acids:
Lactate, Acetoactate, Pyruvate
Alkaline Substances of Human body:
Citrate
Bicarbonates

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The tendency of any acid (HA) to lose proton and form its
conjugate base is defined as Dissociation constant (Ka).

The dissociation constant of acid can be written as

pKa = log 1 / Ka
= -log Ka

pKa is a quantitative measure of acid strength.
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 The Ka and Kb values are usually expressed in moles per liter (mol/L).

The negative log base ten of the Ka value is called pKa, and the negative
log of the Kb value is called pKb.

Smaller pKa (1) refers to Weaker acid - the weaker tendency to dissociate
a Proton.

pKb is the criterion used to estimate the alkalinity of the bases.
It is equivalent to the negative logarithm of base dissociation constant, Kb.

The lesser the pKb, the more stronger the base will be, conversely the
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higher the pKb the more weaker base or alkali.
10
 pH
Sorenson introduced the pH scale in 1909 using the symbol pH ranging from
0 – 14.

pH refers to the H+ ion concentrations.

The concentration of H+ must be expressed in Molar terms i.e. Moles/litre.

The term pH is defined by the expression of
pH = log 1 / [H+]
= -log [H+]
p - denotes the negative logarithm of H+.

In pH scale 0 - 7 refers to Acidic, 7 refers to Neutral and 7 – 14 refers to Basic
or Alkali. 11
For a precisely neutral solution at 250C, in which the concentration of
Hydrogen ions is 1.0 x 10-7M, the pH can be calculated as follows
pH = log 1 / [1.0 x 10-7] = 7.0

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 The pH scale corresponds to the concentration of hydrogen ions.

For example pure water H+ ion concentration is 1 x 10^-7 M,
therefore the pH would then be 7.
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 Definition of Acid Base balance

Acid-base balance refers to the mechanisms, the body uses to keep its
fluids close to neutral pH (that is, neither basic nor acidic) so that the
body can function normally.

Or

Equilibrium between the acid and base elements of the blood and body
fluids is called as acid base balance.

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 Regulation of Acid-Base Balance
The body has three mechanisms to maintain acid-base balance

Buffering The The metabolic
mechanism respiratory or renal
(Blood Buffer) compensation compensation
mechanism mechanism

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 Buffers
Buffers are aqueous systems that tend to resist or prevent the changes in pH of
the solution upon addition of acid (H+) or base (OH-) ions are added.
Buffers are extremely important in biological systems.
Buffers are Mixtures of Weak acids (Proton donor) and their Conjugate
base (Proton acceptor).
Buffers are responsible for maintaining blood pH, maintaining physiological
pH inside cells
Example: Acetic acid (CH3COOH) and Acetate ion (CH3COO-)

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 Buffer systems and important characteristics
A buffer system is a solution that resists a change in pH when acids
or bases are added to it, so much so it enables a suitable
environment for the chemical reactions that requires a certain pH to
occur.
The buffer systems functioning in the blood include bicarbonate-
carbonic acid buffers, phosphate and proteins.

The kidneys help control acid-base balance by excreting hydrogen
ions and generating bicarbonate that helps maintain blood pH within
a normal range. Protein buffer systems work predominantly inside
cells.
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 Importance of Biological Buffer
To maintain homeostasis.

To regulate enzymatic function.

To control pH in biochemical reactions of various metabolic
pathways.

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 BUFFER SYSTEMS OF THE HUMAN BODY
In human body two major types of Buffer systems are responsible for the
maintenance of pH.

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1). Bicarbonate Buffer System:
It is the major buffer system responsible for Extracellular fluid (Blood) pH
maintenance-7.4 (7.35-7.45).
Composition: Sodium bicarbonate (NaHCO3) and Carbonic acid (H2CO3) in
20:1
H++ NaHCO3 ↔ H2CO3 + Na+
OH- + H2CO3 ↔ HCO3- + H2O

2). Phosphate Buffer System:
It is the major buffer system responsible for Intracellular pH maintenance-7.1
- 7.2
Composition: Mono hydrogen phosphate (HPO42-) and Di hydrogen phosphate
(H2PO4-) in 4:1 ratio. This ratio is kept constant with the help of the kidneys.
Thus, phosphate buffer system is directly linked up with the kidneys. H+ +20
2- - - - 2-
3). Protein Buffer System :
Includes hemoglobin and works in blood.

Proteins are made up of amino acids and having
Carboxyl group(-COOH) and Amino group(-NH2).

Carboxyl group gives up H+ where as Amino Group
accepts H+.

Side chains that can buffer H+ are present on 20 amino
acids.

Among all amino acids Histidine(H) and Cysteine(C)
posses buffering capacity.
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Bicarbonate Buffer System 22
23
Hemoglobin as Buffer System

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 ACID BASE DISORDERS
ACIDOSIS: PH 7.45
i) RESPIRATORY ALKALOSIS
ii) METABOLIC ALKALOSIS
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 ACID- BASE BALANCE
The pH of the extracellular fluid of human body
maintaining in the range of 7.35 – 7.45.

The changes in pH leads to Acid-Base imbalance that
may leads to the dysfunction of the Cellular and
metabolic activities.

When the pH of blood is < 7.35, this condition referred as
Acidosis.
When the pH of the blood is >7.45, this condition referred
as Alkalosis.

Two types of conditions in Acidosis and Alkalosis, these
include Respiratory & Metabolic. 26
27
28
 Acid–Base Balance Disturbances

Interactions among the Carbonic Acid–Bicarbonate Buffer System and
Compensatory Mechanisms in the Regulation of Plasma pH.
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 ACIDOSIS ( pH 45mmHg – Hypercapnea.
Chronic conditions:
Depression of respiratory center in brain that controls breathing rate –
drugs or head trauma
Paralysis of respiratory or chest muscles
Emphysema
Asthma
Pneumonia
Pulmonary edema
Obstruction of respiratory tract
Congestive Cardiac Failure 30
 RESPIRATORY ACIDOSIS
Obstruction of air passages due to:
Vomit, Anaphylaxis, Tracheal Cancer

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 Metabolic Acidosis
Bicarbonate (HCO3-) levels decreases (< 22 mEq/Litre) due to loss through
Diarrhea and Renal dysfunction.

The main reason for this condition is untreated diabetes that leads to the
production of excess amount of ketone boides in body; these include
β-Hydroxybutyric acid and Aceto acetic acid.

These ketone bodies are acidic in nature and reduces the pH of the blood
called Ketoacidosis which eventually leads to coma and finally death.

Lacto acidosis – it due to excess of Lactic acid in blood due to strenuous
exercise.
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 Treatment of Metabolic Acidosis
In ketoacidosis, give intravenous fluids, insulin and potassium replacement.
Oxygen is given to the patient diagnosed with lactic acidosis.
In all cases, potassium abnormalities should be carefully treated.
Bicarbonate Requirement
mEq of base needed = body wt in Kg x 0.2 – base excess in mEq/L.

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 ALKALOSIS ( pH - >7.45 )
Respiratory Alkalosis:
Carbonic acid (H2CO3) levels decreases; CO2 levels decreases < 35mmHg
– Hypocapnea.

It is due to hyperventilation and excess removal of CO2.

Metabolic Alkalosis:
Bicarbonate (HCO3-) levels increases (> 26 mEq/Litre).
It is due to excessive loss of acids due to prolonged
vomiting.

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35
Organ dysfunction And Acid Base Imbalance
CNS – respiratory acidosis (suppression) and alkalosis
(stimulation)
Pulmonary – respiratory acidosis (COPD) and alkalosis
(hypoxia, pulmonary embolism)
Cardiac – respiratory alkalosis, respiratory acidosis,
metabolic acidosis (pulmonary edema)
GIT – metabolic alkalosis (vomiting) and acidosis
(diarrhea)
Liver – respiratory alkalosis, metabolic acidosis (liver
failure)
Kidney – metabolic acidosis (RTA) and alkalosis (1st
Aldosterone)

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 ACIDOSIS
decreased failure of metabolic production absorption of prolonged
removal of kidneys to acid of keto acids metabolic acids diarrhea
CO2 from excrete from GI tract
lungs acids

accumulation accumulation excessive loss
of CO2 in blood of acid in blood of NaHCO3
from blood

deep
vomiting
from
respiratory metabolic GI tract
increase in
acidosis plasma H+ acidosis
concentratio kidney
n disease
(uremia)
depression of
nervous system 37
 ALKALOSIS
anxiety overdose high prolonged ingestion of excess
of certain altitudes vomiting excessive aldosterone
drugs alkaline drugs

hyperventilatio loss of acid accumulation
n of base
loss of CO2 and
H2CO2 from
blood

respiratory metabolic
alkalosis alkalosis
decrease
in plasma H+
concentratio
n

overexcitability
of nervous
system 38
 Acidosis and Alkalosis
Respiratory Acidosis Respiratory Alkalosis
A. Pneumonia A. High altitude
B. Bronchitis, Asthma , COPD B. Hyperventilation
C. Pneumothorax C. Hysteria
D. Narcotics, Sedatives D. Febrile conditions
E. Paralysis of respiratory E. Septicemia
muscles F. Meningitis
F. CNS trauma G. Congestive Cardiac Failure
G. Ascites, Peritonitis
Metabolic Acidosis Metabolic Alkalosis
i. High anion gap A. Severe vomiting
A. Diabetic ketosis B. Cushing Syndrome
B. Lactic acidosis C. Milk alkali syndrome
C. Renal failure D. Diuretic therapy (K loss)
ii. Normal anion gap
A. Renal tubular acidosis
B. CA Inhibitors
C. Diarrhea

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Respiratory Acidosis Respiratory Alkalosis
A. Pneumonia A. High altitude
B. Bronchitis, Asthma , COPD B. Hyperventilation
C. Pneumothorax C. Hysteria
D. Narcotics, Sedatives D. Febrile conditions
E. Paralysis of respiratory E. Septicemia
muscles F. Meningitis
F. CNS trauma G. Congestive Cardiac Failure
G. Ascites, Peritonitis
Metabolic Acidosis Metabolic Alkalosis
i. High anion gap A. Severe vomiting
A. Diabetic ketosis B. Cushing Syndrome
B. Lactic acidosis C. Milk alkali syndrome
C. Renal failure D. Diuretic therapy (K loss)
ii. Normal anion gap
A. Renal tubular acidosis
B. CA Inhibitors
C. Diarrhea

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 Acidosis and Alkalosis
Respiratory Acidosis Respiratory Alkalosis
A. Pneumonia A. High altitude
B. Bronchitis, Asthma , COPD B. Hyperventilation
C. Pneumothorax C. Hysteria
D. Narcotics, Sedatives D. Febrile conditions
E. Paralysis of respiratory E. Septicemia
muscles F. Meningitis
F. CNS trauma G. Congestive Cardiac Failure
G. Ascites, Peritonitis
Metabolic Acidosis Metabolic Alkalosis
i. High anion gap A. Severe vomiting
A. Diabetic ketosis B. Cushing Syndrome
B. Lactic acidosis C. Milk alkali syndrome
C. Renal failure D. Diuretic therapy (K loss)
ii. Normal anion gap
A. Renal tubular acidosis
B. CA Inhibitors
C. Diarrhea

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Respiratory Acidosis Respiratory Alkalosis
A. Pneumonia A. High altitude
B. Bronchitis, Asthma , COPD B. Hyperventilation
C. Pneumothorax C. Hysteria
D. Narcotics, Sedatives D. Febrile conditions
E. Paralysis of respiratory E. Septicemia
muscles F. Meningitis
F. CNS trauma G. Congestive Cardiac Failure
G. Ascites, Peritonitis
Metabolic Acidosis Metabolic Alkalosis
i. High anion gap A. Severe vomiting
A. Diabetic ketosis B. Cushing Syndrome
B. Lactic acidosis C. Milk alkali syndrome
C. Renal failure D. Diuretic therapy (K+ loss)
ii. Normal anion gap
A. Renal tubular acidosis
B. CA Inhibitors
C. Diarrhea

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 ANION GAP
The sum of cations and anions in ECF is always equal , so as to maintain the
electrical neutrality.
Commonly measured electrolytes in plasma are Na+, K+, Cl-, HCO3-.
Sodium and Potassium accounts for 95% of cations.
Chloride and bicarbonate accounts for 85% of anions.
There is difference between measured anion and cation.
The unmeasured anion in the plasma constitutes the ANION GAP

The unmeasured anions, i.e. PO4-, SO4-, proteins and organic acids average
- 24 mmol/L.
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 This is due to presence of protein anions, sulphate, phosphate and
organic acids.

Serum Anion Gap (A-):
(Na+ + K+) - (Cl- + HCO3-) = Anion gap

Normally anion gap is about 15 mEq/l

Normal A- range is typically 12 ± 4 mEq/L

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 Calculation of Anion Gap

Na + + K+ = Cl- + HCO3-

140 + 5 = 105 + 25

A- = 15 mEq/L

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 Significance of Anion Gap Calculation

Calculation of Anion gap and its values help in
diagnosing conditions of Acid Base Balance and
Imbalance.

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47
 This is mainly a measure for patients with kidney or gastrointestinal
problems. This test does not definitely point toward any one condition.

Anion gap reveals the presence of metabolic acidosis, where the pH
levels in your body are off-kilter. It differentiates the causes of
metabolic acidosis and helps confirm other findings.

Let’s take for instance that a patient has lactic acidosis (where there's
also a buildup of lactate. In this case, the serum bicarbonate levels will
automatically reduce (because of the buildup) so that when you
calculate for the anion gap, you’ll see that the anion gap increases.

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 High anion gap acidosis (>25)
I. Renal failure
II. Diabetic Metabolic Ketoacidosis
III. Lactic acidosis
IV. Aspirin, Ethylene, Glycol, Methanol, Paraldehyde
Normal anion gap acidosis
I. Diarrhoea
II. Hyperchloremic acidosis
Low anion gap
I. Multiple myeloma
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 Stepwise Approaches
History & physical examination
Arterial blood gas for pH, pCO2, (HCO3-)
Use the HCO3- from ABG to determine compensation
Serum Na+, K+, Cl-, CO2 content
Use CO2 content to calculate anion gap
Calculate anion gap
Determine appropriate compensation
Determine the primary cause

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DIAGNOSTIC LAB VALUES &
INTERPRETATION

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Arterial Blood Gas(ABG )Analyzer determines Acid
Base Balance and Imbalance

Portable ABG Analyzer
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 Diagnosis of Acid-Base Imbalances
1. Note whether the pH is low (acidosis) or high (alkalosis)
2. Decide which value, pCO2 or HCO3- , is outside the normal
range
3. If the cause is a change in pCO2 /H2CO3 the problem is
respiratory.
4. If the change is in HCO3- the problem is metabolic.

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Normal Serum Electrolyte and Arterial Blood Gas
Values  Arterial blood pH = 7.35 -7.45
 Bicarbonate = 22–26 mEq/L
 Chloride = 96–106 mEq/L
 Potassium = 3.5–5 mEq/L
 Sodium = 136–145 mEq/L
 pO2 = 95 (85–100) mm Hg
 pCO2 = 40 (35–45) mm Hg
 Base Excess = -2 to +2

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 Case Study
A patient is in intensive care because he suffered a severe
myocardial infarction 3 days ago. The lab reports the following
values from an arterial blood sample:
pH 7.30
HCO3- = 19 mEq / L ( 22 - 26)
pCO2 = 32 mm Hg (35 - 45)

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Acid-base Parameters are to be Checked in the patients with
Any serious illness
Multi-organ failure
Respiratory failure
Cardiac failure
Uncontrolled diabetes mellitus
Poisoning (barbiturates, ethylene glycol)

56
 Henderson-Hasselbalch Equation
The Henderson-Hasselbalch equation provides a mathematical relationship between
the pH, pKa, and the concentrations of the acid and its conjugate base.

The quantitative relationship among pH, buffering action of a mixture of weak acid
with its conjugate base, and the pKa of the weak acid is given by a simple
expression called Henderson-Hasselbalch Equation.

It allows us to calculate pKa, given pH and the molar ratio of proton donor and
acceptor.
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Henderson Hasselbalch Equation-Bicaronate Buffer

pH= pka +log [HCO3-] / [H2CO3]

At pH 7.4 the ratio of HCO3-/H2CO3 is 20:1.

A buffer is most effective when pH=pKa

When concentration of salt and acid are equal.

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Significance of Henderson Hasselbalch Equation
The equation helps in calculating pH of Buffers based on
known concentrations.

The equation helps in assessing status of Acid Base balance.

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 Practice Questions
What is the normal pH range of human blood?
A) 7.0 - 7.2
B) 7.35 - 7.45
C) 7.5 - 7.7
D) 6.8 - 7.2

Which of the following is the primary buffer system in the human body?
A) Phosphate buffer system
B) Protein buffer system
C) Bicarbonate buffer system
D) Hemoglobin buffer system

A patient presents with a pH of 7.30, pCO2 of 50 mmHg, and HCO3- of 24 mEq/L. What type of acid-base disturbance is
present?
A) Metabolic acidosis
B) Respiratory acidosis
C) Metabolic alkalosis
D) Respiratory alkalosis

Which of the following acids is produced during strenuous exercise due to excess lactic acid in the blood?
A) Ketoacidosis B) Lactic acidosis
C) Sulphuric acidosis D) Pyruvic acidosis
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What is the primary organ responsible for regulating bicarbonate levels in the blood?
A) Lungs
B) Liver
C) Kidneys
D) Heart

In respiratory alkalosis, what would you expect the bicarbonate (HCO3-) levels to be?
A) Decreased
B) Increased
C) Normal
D) Variable

Which of the following statements is true regarding respiratory acidosis?
A) It is caused by excessive loss of carbon dioxide.
B) It can result from conditions like COPD.
C) It is characterized by a high pH.
D) It is primarily a metabolic disorder.

Which of the following substances is responsible for the regulation of intracellular pH?
A) Phosphate buffer system
B) Bicarbonate buffer system
C) Ammonia buffer system
D) Citrate buffer system
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What happens to pH in metabolic alkalosis?
A) Decreases
B) Increases
C) Remains the same
D) Fluctuates

Which of the following can be a cause of respiratory alkalosis?
A) Severe diarrhea
B) Anxiety or panic attacks
C) Kidney failure
D) Renal tubular acidosis
Answer: B) Anxiety or panic attacks

Which of the following conditions can lead to metabolic acidosis?
A) Vomiting
B) Hyperventilation
C) Diabetic ketoacidosis
D) Excessive antacid intake

Which of the following is a conjugate base of carbonic acid?
A) HCO3-
B) H2CO3
C) OH-
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D) NaHCO3
Thank
You
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