Solutions. Acid–base equilibrium in biological systems
Plan
The theory of electrolytic dissociation
Dissociation of bases, acides and salts in water solutions
Acides are compounds dissociating in aqueous solutions with the formation of positive ions of one species – hydrogen ions. HCl→H+ + Cl- Bases are compounds dissociating in aqueous solutions with the formation of negative ions of one species – hydrox
Degree of dissociation α
Strong electrolytes
Weak electrolytes
The dissociation of weak electrolytes is a reversible process
The equilibrium constant K is called the dissociation (ionization) constant
Ostwald dilution law
Acidity and basicity constants
Dissociation of water
Hydrogen ion exponent
Protolytic theory
Salt - the reaction product of acid and base
The homeostasis. The importancy of pH maintenance in human body
The constancy of hydrogen ions concentration is one of important constant of internal medium of organism, because:
pH values of different biological fluids and tissues of the human body
The concept of buffer solutions
The resistive action is the result of the equilibrium between the weak acid (HA) and its conjugate base (A−):
Henderson-Hasselbah equation
Buffer capacity
Buffer capacity
Hydrocarbonate buffer system
Alkaline reserve
Phosphate buffer system
Protein buffer systems
PROTEIN acid-base buffer system
Hemoglobin buffer system
Hemoglobin acid-base buffer system BLOOD
Binding of hydrogen cations imidazole groups of hemoglobin.
Hemoglobin buffer system
In vessels of tissues
In vessels of tissues
In lungs
In lungs
Acidosis and alkalosis
Literature
3.81M
Category: chemistrychemistry
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Solutions. Acid–base equilibrium in biological systems

1. Solutions. Acid–base equilibrium in biological systems

2. Plan

• 0. Solutions and their colligative properties
• 1. The theory of electrolytic dissociation. Dissociation of
bases, acides and salts in water solutions.Strong and weak
electrolytes
• 2. Protolytic theory.
• 3. Dissociation of water. Hydrogen ion exponent.
• The homeostasis.
• 4. The importancy of pH maintenance in human body.
5. The concept of buffer solutions.
• 6. Hydrocarbonate buffer system
• 7. Phosphate buffer system
• 8. Protein buffer systems
• 9. Hemoglobin buffer system
• 10. Acidosis and alkalosis. Treatment of acidosis and
alkalosis.

3.

4.

5.

6.

7.

8.

9.

10.

11.

12.

13.

14.

15.

16.

17.

18.

19.

1. Theory
of
electrolytic
dissociation (Arrhenius’ theory).
2. Protolytic theory (Bronsted –
Lowry’ theory).
3. Electronic
theory
(Lewis’
theory).

20. The theory of electrolytic dissociation

21.

Substances
Electrolytes
solutions or
melts conduct
electric current
Non- electrolytes

22.

Electrolytic dissociation –
process of decomposition
of solutes in the solvent into ions.
HNO3
NH4Cl
KOH
+
H
+NO3
+
NH4 +Cl
+
-
K +OH

23.

• 1)
Substances dissociating in solutions or melts
into positively charged Cat+(cations) and negatively
charged An- (anions). The latter include acids, bases
and salts.
2)
In electric field Cat+ move to cathode, Anmove to anode.
3)
Electrolytes decompose into ions in different
degree.
4)
Dissociation depend of:
a) nature of electrolyte;
b) nature of solvent;
c) concentration;
d) temperature.

24. Dissociation of bases, acides and salts in water solutions

25. Acides are compounds dissociating in aqueous solutions with the formation of positive ions of one species – hydrogen ions. HCl→H+ + Cl- Bases are compounds dissociating in aqueous solutions with the formation of negative ions of one species – hydrox

Acides are compounds dissociating in aqueous solutions with the
formation of positive ions of one species – hydrogen ions.
HCl→H+ + ClBases are compounds dissociating in aqueous solutions with the
formation of negative ions of one species – hydroxide ions OH-.
Ca(OH)2→Ca2++ 2OH-
Medium salts dissociate to form metal cations and anion of acid
radical.

26.

Strong and weak electrolytes

27. Degree of dissociation α

Ni
Ni
100%
Ntot
Ntot
Ni - the number of molecules, dissociating into ions;
Ntot – the total number of dissolved molecules.

28.

Classification of electrolytes
weak
medium
strong
α<3%
3%< α<30%
α>30%

29. Strong electrolytes

Majority of salts.
Some acids (HCl, HBr, HI, HNO3,
HClO4, H2SO4).
Alkalis (LiOH, NaOH, KOH,
RbOH, CsOH, Ca(OH)2 ,
Sr(OH)2, Ba(OH)2)

30. Weak electrolytes

Majority of acids and bases
(H2S, H2CO3, Al(OH)3, NH4OH).

31. The dissociation of weak electrolytes is a reversible process

CatAn
Cat+ + An-

32. The equilibrium constant K is called the dissociation (ionization) constant

C
C
Cat An
K
C
CatAn

33. Ostwald dilution law

α 2 См
Кd =
1 α
Because in solutions of weak electrolytes, degree of dissociation of a very
small quantity, 1-α = 1, then
Кd = α См
2
Dissociation constant, Kd, and the degree of dissociation,
M is the molar concentration of the solution. Very often,
instead of the dissociation constants are in their common logarithms:
рК = lg Кd

34. Acidity and basicity constants

• The dissociation constants of acids and bases,
respectively called acidity constants (KA) and
major (KB).
• Product constant acidity and basicity constants,
with the acid conjugate base is the ion product of
water:
Ка Кв = Кw
рКа + рКв = 14

35.

36. Dissociation of water

H2O
H+ + OH-
C
C
H
OH
K
C
H
2O

37.

14
H
O H
OH
2
K
K
C
C
C
10
w
Kw is constant, ion product of water.

38. Hydrogen ion exponent

pH= -lg [H+]

39.

pH Measurement
• indicators
• pH - meters

40.

41. Protolytic theory

• Danish physicist and chemist Johannes Brønsted
and the English chemist Thomas Lowry in 1928-1929
was offered Protolytic (protonic) theory of acids
and bases, according to which:

42.

• Base - a substance (particle) that can attach proton (i.e.
base - proton acceptor).
• Acid- a substance (particle) that can donate proton (i.e.
acid – proton donor)
• In the general form:
A
+
-
H +B
А-(acid); B-(base).
Such a system, consisting of acids and bases called protolytic conjugate pair of
acid and base, offsetting or appropriate

43. Salt - the reaction product of acid and base

• Example:
HClO 4
Conjugated
acid
NH3+H+
Conjugated base
+
H
+ClO 4
Conjugated
base
+
NH4
Conjugated
acid
By this theory, acids and bases may be both neutral molecules
and ions (cations and anions).

44. The homeostasis. The importancy of pH maintenance in human body

The human body has mechanisms of
coordination of physiological and
biochemical processes proceeding inside
it and maintenance constancy of internal
medium (optimal value of pH, levels of
different substances, temperature, blood
preassure). This coordination and
mantanance are called homeostasis.

45. The constancy of hydrogen ions concentration is one of important constant of internal medium of organism, because:

1) Hydrogen ions have catalytic effect on many
biochemical processes;
2)Enzymes and hormones exhibit biological activity
only at a specific range of pH values;
3)Small changes of pH in blood and interstitial fluids
affect the value of the osmotic pressure in this
fluids.

46. pH values of different biological fluids and tissues of the human body

Biological fluid
pH (normal)
Blood plasma
7.40±0.04
Saliva
6.35-6.85
Gastric juice
0.9-1.1
Urine
4.8-7.5
Cerebrospinal liquor
7.4±0.05
Pancreatic juice
7.5-8.0
Bile in bladder
5.4-6.9
Milk
6.6-6.9
Lacrimal fluid
7.4±0.1
Skin
6.2-7.5

47. The concept of buffer solutions

Buffer solutions are solutions that resist
change in hydrogen ion and the
hydroxide ion concentration (and
consequently pH) upon addition of
small amounts of acid or base, or
upon dilution.

48.

49. The resistive action is the result of the equilibrium between the weak acid (HA) and its conjugate base (A−):

H+(aq) + A−(aq) → HA(aq)
OH-(aq) + HA(aq) → A−(aq) +H2O(l)

50. Henderson-Hasselbah equation

C
b
pH
pK
lg
a
C
a

51. Buffer capacity

• Buffer capacity (B) - the number of moles of
equivalents of strong acid or alkali to be added to 1
liter of buffer solution to shift the pH unit
CH (HA) V(HA)
,
• Вac.=
pH pH 0 V
• Вbas.=
CH (B) V( B)
,
pH pH 0 V

52. Buffer capacity

• Buffer capacity is maximal at a ratio of acid
salt 1:1 => pH = pK.
• Good – at [pK+0.5, pK-0.5]
• Sufficient – at [pK+1, pK-1]
• The higher the concentration of the solution, the
greater the buffer capacity. The concentration of
acid and salt in the buffer solutions usually about 0.050.20 M.

53.


The relative contribution% buffer
systems in the blood to maintain
homeostasis it protolytic
Buffer systems plasma
Hydrogen carbonate 35%
Protein 7%
Hydrogen phosphate 1%
TOTAL 43%
Buffer systems erythrocytes
Hemoglobin 35%
Hydrogen carbonate 18%
Hydrogen phosphate 4%

54. Hydrocarbonate buffer system

HCO3- +H+
H2CO3+OHCO2+ H2O
H2CO3
HCO3-+ H2O
H2CO3
3
[
HCO
]
pH
pK
lg
a
[
H
CO
]
2
3

55.

• pKa1(H2CO3)=6.1
• pH of a blood plasma = 7.4
3
[
HCO
]
7
.4
6
.1
lg
[
H
CO
]
2
3
3
[
HCO
]
lg
7
.
4
6
.
1
1
.
3
[
H
CO
]
2
3
3
[
HCO
] 1.3
10
19
.
95
20
[
H
CO
]
2
3

56. Alkaline reserve

HCO3-+ H+
H2CO3
CO2+ H2O

57. Phosphate buffer system

HPO42-+H+
H2PO4-+OH-
H2PO4HPO42-+H2O
2
4
2 4
[
HPO
]
pH
pK
lg
a
[
H
PO
]

58.

• The mechanism of action of phosphate buffer:
• 1. acid addition
• 2 Na++HPO42–+H++Cl - NaH2PO4+Na++Cl • 2. adding alkali :
• NaH2PO4 + NaOH Na2HPO4 + H2O
• Excess hydrogen phosphate monobasic and removed
through the kidneys. Full recovery of relations in the buffer occurs
only 2-3 days.

59.

pKa(H2PO4-)=6.8
pH of a blood plasma = 7.4
2
4
2 4
[
HPO
]
7
.4
6
.8
lg
[
H
PO
]
2
4
2 4
2
4
2 4
[
HPO
]
lg
7
.
4
6
.
8
0
.
6
[
H
PO
]
[
HPO
] 0
.
6
10
3
.
98
4
[
H
PO
]

60. Protein buffer systems

The plasma proteins (albumins, globulins) are less important than
the hemoglobin for maintenance of pH.

61. PROTEIN acid-base buffer system

62. Hemoglobin buffer system

63.

64. Hemoglobin acid-base buffer system BLOOD

65. Binding of hydrogen cations imidazole groups of hemoglobin.

66. Hemoglobin buffer system

HHb + O2
HHbO2
Hemoglobin is a weaker acid (pKa HHb = 8.2) than
oxyhemoglobin (pKa HHbO2 = 6.95). Therefore Hb- ions
being anions of weaker acid are capable stronger to bind H+
ions than HbO2- ions.
Undissociated molecules HHbO2 lose O2 easier than
the ions HbO2-

67.

a)the hemoglobin buffer system:
HHb
H+ + Hb-;
b)the buffer system formed by
oxyhemoglobin:
HHbO2
H+ + HbO2-.

68.

In erythrocytes:
HHbO2
HHb + O2 (1)
+
HHbO2
H + HbO2 (2)
HbO2
Hb + O2 (3)

69. In vessels of tissues

70.

71. In vessels of tissues

CO2+ H2O
HbO2-+ H2CO3
HHbO2
H2CO3
HHbO2 + HCO3HHb + O2

72. In lungs

73.

74. In lungs

HHb + O2
HHbO2+ HCO3-
H2CO3
HHbO2
HbO2-+ H2CO3
CO2+ H2O

75. Acidosis and alkalosis

Acidosis
Alkalosis
Gaseous (respiratory)
Gaseous (respiratory)
Non gaseous
-metabolic;
-excretory;
- exogenous.
Non gaseous
-metabolic;
-excretory;
- exogenous.

76. Literature

1. Medical Chemistry : textbook / V. A. Kalibabchuk [and al.] ;
ed. by V. A. Kalibabchuk. - K. : Medicine, 2010.
2.http://www.chemeurope.com/en/encyclopedia/Buffer_solution.
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