Acid-base disturbance - PowerPoint PPT Presentation

1 / 86
About This Presentation
Title:

Acid-base disturbance

Description:

Acid-base disturbance Zhao Mingyao BMC.ZZU – PowerPoint PPT presentation

Number of Views:133
Avg rating:3.0/5.0
Slides: 87
Provided by: glf2
Category:

less

Transcript and Presenter's Notes

Title: Acid-base disturbance


1
Acid-base disturbance
Zhao Mingyao BMC.ZZU
2
  • Acid? ------- Base?
  • pH in arterial blood 7.357.45

3

H concentration in body fluid
  • ECF H
    mol/L pH
  • Arterial blood 4.0 10-8 7.40
    0.05
  • Venous blood 4.5 10-8 7.35
  • Interstitial fluid 4.5 10-8
    7.35
  • Intracellular fluid 1.0 10-6 6.0
  • to 4.0 10-8
    7.4
  • Gastric fluid
    0.91.8 (3.0)
  • Pancrea fluid
    7.8 8.4

4
Metabolic processes generate acids
Cells
H 100 nmol/L (pH 7)
H
H
Artery
H 36 nmol/L pH7.4
H
H
H 44 nmol/L pH7.36
Capillary
Vein
5
  • Section 1 Acid-base biochemistry

6
1. Generation of Acid-Base
  • (1) Sources of acid
  • 1)volatile acid
  • CO2 H2O ? H2CO3 ? H HCO3-
  • ( H
    15 mol /d)
  • 2)fixed acid (non-volatile acid)
  • phosphoric, sulfuric, lactic, ketone
    bodies etc.
  • H 0.05 0.10 mol /d

7
Sources of acid in body
8
(2) Sources of bases 1)products of
metabolism (small amounts)Such as ammonia (NH3)
2)dietary intake(vegetables and fruits)
sodium citrate
acids production gtgtbases, in commen
renal reabsorption

9
renal reabsorption

pH 7.357.45 in Arterial blood
10
2. Henderson-Hasselbalch Equation
HCO3-
pHpKalg
H2CO3
6.1 lg HCO3- / 0.03 PCO2 6.1 lg 24 /
1.2 7.4
6.1 1.3 7.4
pH 7.357.45
11
HCO3-
pH ?
H2CO3
12
Strong acid pulse
pH
?
Strong base pulse
20

( eg . 24/1.2 or 40/2 or 10/0.5)
1
20
?
( lt20/1 or gt20/1 )
1
13
Henderson-Hasselbalch Equation
  • Compensatory pH normal, but ? change
  • Decompensatory pH, HCO3 -, H2CO3 change


HCO3-
?
pH
H2CO3
14
fulcrum
Relationship between Henderson-Hasselbalch
Equation and pH
15
  • Section 2 Regulation of acid-base
  • in body fluid

16
What happens in its body
H
iv lactic acid
iv bicarbonate
?
?
?
?
acidosis
alkalosis
death
death
?H?
7.8
7.35 7.45
6.8
pH
17
Why does body keep acid-base balance of body
fluid ?
H
Cellular signal
? Enzyme ATP
cell
Ion distribution? electrical action
18
  • body maintain humoral acid-base balance by
  • 1. blood buffer system
  • 2. lung
  • 3. kidney
  • 4. cell

19
1. Blood buffer system

HCO3- / H2CO3 Hb- / HHb Pro- / HPro HPO42-
/ H2PO4-
A-/HA
Buffer system can bind and release H
Dissociated buffer H H undissociated
buffer
20
HCO3- / H2CO3 determines the pH of blood
  • pH pK lg HCO3- / H2CO3
  • HCO3- / H2CO3 is the major extracellular
  • buffer 53
  • H2CO3 regulated by lung
  • HCO3- regulated by kidney






21
2. Pulmonary regulation
22
Pulmonary regulation
Central control
PaCO2
CNS
chemoreceptor

Peripheral chemoreceptor
respiration
PaO2?pH?PaCO2
in the carotid and aortic bodies
peripheral regulation
23
3. Renal regulation
excreting H keeping base
(1) bicarbonate reabsorption (NaHCO3)
(2) phosphate acidification
(3) ammonia excretion
24
(1)Reabsorption of HCO3- in different segments of
renal tubule
25
Bicarbonate reabsorption in proximal tubules
Na
CA
26
(2) Phosphate acidification in distal tubules
ATP
Cl-
27
(3) Ammonia excretion in proximal tubular cells
  • Glutamine
    Tubular

  • lumen
  • glutaminase

  • NH3 NH3
  • ?-ketoglutaric acid

  • NH4 NH4
  • H2CO3
    Na
  • Na
  • HCO3- H
    H

ATP
28
(No Transcript)
29
4. cellular buffer
  • H-K exchange between intra- and extra- cell
  • Cl--HCO-3 exchange between intra- and extra-RBC
    or/ gastric cell

30
Section 3 Laboratory tests
  • Parameters of acid-base representing
  • pH
  • PaCO2
  • HCO3- ( SB, BE, BB )
  • Annion gap

31
1. pH in normal level
(1) true normal (2) compensatory (3) mixed
with opposite effect
32
(No Transcript)
33
Weak tolerance to alkalosis
7.35 7.45
6.8
pH
7.8
acidosis
alkalosis
death
death
16 nmol/L
40
160
?H?
34
2. Partial pressure of CO2, PaCO2
tension produced by CO2 dissolved physically in
plasma
Normal 40mmHg (3545) H2CO3 40
0.03 1.2mmol/L
PaCO2? Res Acidosis or ?PaCO2 ?Res alkalosis
or ?
35
3. HCO3-
normal 24 mmol/L (2227)
SB and AB
BB
BE
Primary and secondary change ?
36
4. Anion gap (AG)
AG UA UC UA Undetermined anion UC
Undetermined cation
37
AG UA - UC


Cl- (104)
Na (140)
Na UC Cl- HCO3- UA
AG Na - Cl- - HCO3- 140-104-24
12 (mmol/L)
HCO3- (24)
AG
UA (23)
UC (11)
Normal 1014mmol/L
Distinguishing metabolic acidosis
38
An elevated Anion Gap always strongly suggests a
Metabolic Acidosis
  • If AG is 20-30 then high chance (67) of
    metabolic acidosis
  • If AG is gt 30 then a metabolic acidosis is
    definitely present

39
Summary of indexes
1. pH 2. Metabolic factor HCO3- SB, BB,
BE, AG 3. Respiratory factorPaCO2

40
Section 4 Simple acid-base disorders
  • Concept
  • Compensation

41
Classification of
42
Analysis of simple acid-base disorder
7.4?
43
  • Part 1 Metabolic acidosis
  • Concept HCO3-p ? primarily

44
Changes of laboratory test
Primary pH ? HCO3- ? Secondary
PaCO2 ? Kb?
45
Classification
  • Met acidosis with High AG
  • Met acidosis with Normal AG

46
Met acidosis with normal AG
Comparison between Met acidosis with High AG and
normal AG
47
1. Cause and mechanisms
  • (1) fixed acid production? lactic acidosis,
    ketoacidosis, excess acetylsalicylic acid , drugs
    yielding hydrochloride acid
  • (2) fixed acid removing? RTA, RF
  • (3) HCO3- loss? diarrhea , intestinal suction
  • (4) hyperkalemia
  • (5) hyperchloremia

48
2. Compensation of body
(1) Blood buffer system (2) lung (3) kidney (4)
cell
49
3.Effects on the body
(1) Cardiovascular system
  • Inhibiting myocardial contraction
  • Arrythmia
  • Responsibility?of vessel to
  • catecholamine

50
(2) Central nervous system
  • Cerebral energy production?
  • GABA ?

decarboxylase ()
Glutamate
GABA?
51
(3) Hyperkalemia
52

4. Principle of prevention treatment
1.Treatment of primary disease
2.Supplement of base NaHCO3 THAM( Tris,
Trishydroxymethyl amino methane, C4H11NO3 )
lactic sodium
3.Correcting and preventing water, electrolytes
disorders
53
  • Part 2 Respiratory acidosis

Concept H2CO3 p?primarily
54
Changes of laboratory test
Primary pH ? PaCO2
? Secondary HCO3- ? Kp ?

55
1. Causes and mechanisms
  • Excreting CO2 ?
  • Inhaling excessive CO2

56
2. Compensation of respiratory acidosis
Blood Lung Kidney cell
H2CO3 p?
57
Changes of laboratory test
Acute pH PaCO2 HCO3-
PaCO2 10mmHg
HCO3- compensatory ? 1 mmol/L
Chronic pH PaCO2 HCO3-
PaCO2 10mmHg
HCO3- compensatory? 3.5 mmol/L
Cl- ?
K ?
58
3. Effect of
Similar to Met Acidosis, but obvious sign of CNS
  • CNS Acidosis
  • Cerebral blood flow?
  • With hypoxia in same time

59
4. Principle of prevention treatment
(1)improving alveolar ventilation
(2)supplement of base
60
  • Part 3 Metabolic alkalosis

Concept HCO3-p ?primarily
61
Changes of laboratory test
Primary pH ? HCO3- ? Secondary PaCO2
? Kb ?
62
  • 1.Causes and mechanisms
  • Base intake ?
  • H loss ?
  • Hypokalemia
  • hypochloremia
  • Volume contraction

63
Classification saline-responsive alkalosis
---- induced by hypochloremia
saline-resistant alkalosis ---- induced by
nonhypochloremia
64
2. Compensation
(1) Blood buffer system ( limited ) (2) lung (3)
kidney (4) cell
HCO3-
pH?
H2CO3
65
3. Effects
(1) CNS ?
  • GABA?

decarboxylae (-)
Glutamate
GABA ?
Hypoxia
GABA transaminase ()
succinate semialdehyde
66
(2)Neuromuscular excitability
  • mechanism
  • pH?,Free Ca2b?
  • CNS

67
(3) left-shift of oxyhemeglobin
dissociation curve
68
(4) Hypokalemia
69
4. Principle of prevention treatment
  • (1)Treatment of primary disease
  • (2)Normal saline
  • ? saline-responsive alkalosis
  • saline-resistant alkalosis
  • CA inhibitor
  • ADS inhibitor
  • (3)Acid-containing drug

70
  • Part 4 Rrespiratory alkalosis

H2CO3p ?primarily
71
Changes of laboratory test
Primary pH ? PaCO2 ? Secondary
HCO3- ? Kp ?
Cl-p ?
72
1. Causes and mechanisms
Excreting excessive CO2
(1) Hypotonic hypoxia (2) Disease of CNS
(3) Psychological factors (4) Hypermetabolism
(5) Drugs
73
2. Compensation of respiratory alkalosis
Blood Lung Kidney cell
?
H2CO3 p?
74
Compensatory changes
Acute PaCO2 ? 10 mmHg HCO3-
compensatory ? 2 mmol/L
Chronic PaCO2 ? 10 mmHg HCO3-
compensatory ? 4 mmol/L
75
3. Effect of
  • Similar to Met Alkalosis

Rapid and obvious
76
4.Principle of prevention treatment
1.treatment of primary disease
2. inhaling CO2 (Paper mask or 5 CO2 )
77
(No Transcript)
78
Section 5 Mixed acid-base disorders
79
Mixed acid-base disorders
  • Double acid base disorders
  • Metabolic Metabolic
  • acidosis
    alkalosis
  • Respiratory Respiratory
  • acidosis
    alkalosis

80
Double acid-base disorders and pH change
Type HCO3- / H2CO3 20/1 pH
Met acid Res acid ?/? ? ?
Met acid Res alko ?/ ? ? ? ?
Met acid Met alko ?/ ? ? ? ?
81
? R acidosis M acidosis M alkalosis
? R alkalosis M acidosis M alkalosis
Triple Acid-base disturbances
82
Summery
  • Metabolic acidosis is induced by primary decrease
    of HCO-3 owing to increased production or
    retention of fixed acides or HCO-3 loss.
  • Metabolic alkalosis is induced by primary
    increase of HCO-3 due to H loss.
  • Respiratory acidosis or alkalosis is induced by
    primary increase or decrease of CO2 caused by
    hypoventilation or hyperventilation.

83
  • Acidosis depresses activity of CNS and myocardial
    contractility, and induces cardiac arrhythmia
    and vasodilation.
  • Alkalosis results in dysfunction of CNS and
    cramping.
  • Different kinds of acid-base disorders may
    coexist in patients.

84
Scientific poem
H ion in body life
H ion You, we love You, we also hate So a little
change You let life lost forever
___ ?
85
(No Transcript)
86
End
THANKS
Write a Comment
User Comments (0)
About PowerShow.com