1. AB balance
Acidosis
Alkalosis

2. - log [H+] = pH

3. AB values in plasma [ H+] (nmol/l) 38 – 42 pH 7.36 – 7.44
PCO2 (kPa) – 5.5
[ HCO3- ] (nmol/l) – 26

4. AB values in plasma [ H+] (nmol/l) 38 – 42 pH 7.36 – 7.44
PCO2 (kPa) – 5.5
[ HCO3- ] (nmol/l) – 26
Base excess ­2.5 – +2.5
Anion gap = (Na++K+) - (Cl-+HCO3-)

6. x x Changes in ABB Acidosis Alkalosis Respiratory Metabolic PCO2
Acidemia
Alkalemia
Respiratory
Metabolic x
PCO2
[ H+], [ HCO3- ]

7. ABB Buffers Compensation
Bicarbonate
HCO3- / CO2
Buffers
Non-bicarbonate
Hb- / oxy-Hb-
H2PO4-, NH4+
Lungs
Compensation
Kidney
+ Liver

8. METABOLIC ACIDOSIS I 1. Cause – increased production / intake H+
Diabetes mellitus, starvation
-oxidation FA  ketoacids
Exrcise, hypoxia
anaerobic glykolysis  lactate
Poisoning by acid

9. METABOLIC ACIDOSIS II 2. Cause – kidney disorder Disfunction
loss of HCO3
retention H+
Disfunction
lumen
proximal tubule
blood
H +
H2O
HCO3- + H+
HCO3- resorption
CAIV
OH -
CAII
HCO3-
CO2
CO2
H+ ATPáza
ATP
H +
H2O
H+ elimination
OH -
HCO3- resorption
HCO3-
CAII
CO2

10. METABOLIC ACIDOSIS III
3. Cause / result – hyperkalemia
ATP
Na+ K+
[ H+]
[ K+]
Acidosis  Hyperkalemia

11. Henderson - Hasselbach equation
- log [H+] = pH
H+ + HCO3- = CO2 + H2O
[HCO3-]
————
PCO2
pH = pKa + log
6.1
e‘kweižn

12. Henderson - Hasselbach
- log [H+] = pH
H+ + HCO3- = CO2 + H2O
pH = log
[HCO3-]
————
PCO2
[HCO3-]
[CO2]
8.0
7.4
7.0

13. MAC H+
H+ + HCO3-  CO2 + H2O
[HCO3-]
[CO2]
8.0
7.4
7.0

14. MAC H+
2H+ + HCO3-  CO2 + H2O
[HCO3-]
[CO2]
8.0
7.4
7.0

15. MAC H+
2H+ +2HCO3-  CO2 + H2O
[HCO3-]
[CO2]
Buffer
8.0
7.4
7.0

16. MAC H+
2H+ +2HCO3-  2CO2+ 2H2O
[CO2]
[HCO3-]
8.0
7.4
7.0

17. MAC H+ 2H+ +2HCO3-  2CO2+ 2H2O [HCO3-] [CO2] 8.0 7.4 7.0
Chemoreceptors stimulation

18. MAC H+ 2H+ +2HCO3-  2CO2+ 2H2O Expiration by lungs [HCO3-] [CO2]
8.0
7.4
7.0
1) Buffer: Bicarbonate
Chemoreceptors stimulation
2) Lungs: hyperventilation
3) Kidney:  elimination H+ ,  resorption HCO3-

19. Metabolic acidosis - summary
acetoacetát a β-hydroxybutyrát

20. Compensation of MAL METABOLIC ALKALOSIS Cause:
Increased bicarb. uptake
infusion HCO3-
Vomiting
loss of H+
Hypokalemia
Alkalosis  Hypokalemia
Compensation of MAL
Hypoventilation - impossible !
Kidney:  elimination HCO3- !!!

21. Compensation of RAC RESPIRATORY ACIDOSIS retention CO2  [H+]  pH
Cause:
Lung, thorax disorder
CO2 + H2O  H+ + HCO3-
Compensation of RAC
2) Kidney:  elimination H+ , NH4+ , resorption HCO3-
1) Buffers: non-bicarbon. bufers

22. RESPIRATORY ALKALOSIS
Cause:
Hyperventilation, high altitude
decrease of PCO2
[H+]
 pH
CO2 + H2O  H+ + HCO3-
Compensation of RAL
1) Buffer inf.: non-bicarb.
adding H+
2) Kidney:  elimination HCO3-,  sekretion H+

23. Questions
Questions

24. Q 11
Q11: Match each item in the top (lettered) column with appropriate item in the bottom (numbered) column. “Increased” or “decreased” is used with reference to normal physiological values.
Diabetic ketoacidosis
Hypoventilation
Excessive ingestion of sodium bicarbonate
Increased plasma pH, increased plasma bicarbonate, alkaline urine
Decreased plasma pH, decreased plasma bicarbonate, acidic urine
Decreased plasma pH, increased plasma bicarbonate, acidic urine
Increased plasma pH, increased plasma bicarbonate,
alkaline urine c.
Decreased plasma pH, decreased plasma bicarbonate,
acidic urine a.
A11:
a – 2
b – 3
c - 1
Decreased plasma pH, increased plasma bicarbonate,
acidic urine b

25. What pH would be in the urine of vegetarian?
Vegetarians food
rich in HCO3-
Increased uptake of basis 
Compensation by kidney
HCO3- in urine
Alcalic urine 

26. What is the first aid in panic attack, why?
Hyperventilation
Decrease of PCO2 on plasma  
First aid: reinhalation of CO2
Ventilation into the bag 

27. Lung illness Lung illness Restrictive Obstructive air passage (AP)
Bronchoconstriction
Inflammation, mucus
Bronchus tumour
Surrounding compression – nodule …
Lung fibrosis
Edema
Atelektasis
Pneumothorax …
Atelektáza – zkolabovaná část plic-bez vzduchu-např ucpání hlenem, při operaci, velký plicní odpor
collaps
weaken
[ˈwiːkən] oslabit (se) , 
Mucus_mju:k s
Whistling pískoty
Nodule nodju:l zduřelá uzlinka
 Resistance AP
 Lung compliance
Expiratory whistling
 Respiratory motion
Inspiratory position of the thorax
Weakened breading 27

28. Why not to serve oxygen to the patient with COPD ?
Chronic obstructive pulmonary disease
Retention of CO2  Chronic respiratory acidosis
Adaptation of central chemoreceptors 
Periferal chemoreceptors - stimulated by low pO2 
100%O2 might abolish this hypoxic drive ! O2

29. What is the cause of death in MAC?
Na+
[ K+]
[ H+]
Diarrhea
loss of HCO3- in GIT 
Metabolic acidosis
Hyperkalemia
Change in RMP, depolarization 
Neuromuscular irritability 
Vetricular fibrilation 
EKG

30. transport in distal tubule
Hypo-, hyper-calcemia
transport in distal tubule
Arthur C. Guyton, John E. Hall, Textbook of Medical Physiology
Elsevier, 10th edition (2000) 

31. Cell response to intracellular acidosis or alkalosis
Boron

32. Buffer systems

33. HCO3- proximal, ascending loop
Proximal tubule, thick ascending loop of Henle, early distal tubule
HCO3- proximal, ascending loop
Na+-H+ exchanger
Arthur C. Guyton, John E. Hall, Textbook of Medical Physiology
Elsevier, 10th edition (2000)  33

34. Arthur C. Guyton, John E. Hall, Textbook of Medical Physiology
Dist tub HCO3-
Late distal tubule and collecting duct
Cl- - HCO3- exchange
Urine H+ incerased 900x
Arthur C. Guyton, John E. Hall, Textbook of Medical Physiology
Elsevier, 10th edition (2000)  34

35. Phosphate buffer Proximal and early distal tubule 35
Arthur C. Guyton, John E. Hall, Textbook of Medical Physiology
Elsevier, 10th edition (2000)  35

36. Role of liver in ABB proteine metabolism ammonia (NH3)
ammonium ion (NH4+) 36

37. Arthur C. Guyton, John E. Hall, Textbook of Medical Physiology
Proximal tubule, thick ascending limb of the loop of Henle, distal tubule
NH4+ proxi
Arthur C. Guyton, John E. Hall, Textbook of Medical Physiology
Elsevier, 10th edition (2000)  37

38. Arthur C. Guyton, John E. Hall, Textbook of Medical Physiology
Collecting duct
NH4+ collect
ammonia (NH3)
ammonium ion (NH4+)
Arthur C. Guyton, John E. Hall, Textbook of Medical Physiology
Elsevier, 10th edition (2000)  38

39. Transport CO2 1.
2. in plasma

40. Diagnosis of Acid-Base Imbalances
Acidosis or alcalosis? Note whether the pH is low (acidosis) or high (alkalosis)
Respiratory or metabolic? Decide which value, pCO2 or HCO3- , is outside the normal range and could be the cause of the problem. If the cause is a change in pCO2, the problem is respiratory. If the cause is HCO3- the problem is metabolic.
No or partial compensation? Look at the value that doesn’t correspond to the observed pH change. If it is inside the normal range, there is no compensation occurring. If it is outside the normal range, the body is partially compensating for the problem

41. Example
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 7.3
HCO3- = 20 mEq / L ( )
pCO2 = 32 mm Hg ( )
??Diagnosis??
Acidosis
Metabolic
With compensation

42. summary Full compensation - pH in normal rank (7.35 - 7.45)
numbness [nʌmnɪs] noun (podstatné jméno)
necitlivost , znecitlivění , zmrtvění (po umrtvení ap.)
Full compensation - pH in normal rank ( )
Partial compensation - pH still shifted

43. Respiratory acidosis kongestivní srdeční selhání
kongestivní srdeční selhání – městnavé srdeční selhání. Je provázeno výrazným zadržením vody a sodíku v těle s tvorbou otoků, popř. i hromaděním tekutiny v tělesných dutinách hrudní, břišní, srov. transudát. Tento stav je jedním z příkladů sekundárního hyperaldosteronismu. K odstranění nadbytečné tekutiny se podávají mj. diuretika, důležité je však i omezení příjmu soli v potravě. Srov. městnání kongesce

44. Respiratory alkalosis

45. Metabolic acidosis

46. Metabolic alkalosis

47. …………..