M. GANDUL ATIK YULIANI, MKES., DRH. - s1.fkh.unair.ac.ids1.fkh.unair.ac.id/images/PPT/Body...

M. GANDUL ATIK YULIANI, MKES., DRH.

LIQUID BODY, ELECTROLYTE

AND BASE ACID BALANCE

I. BALANCE OF WATER AND ELECTROLYTE

II. CONDAYS

THE BALANCE OF WATER AND

ELECTROLYTES

BODY LIQUID PHYSIOLOGY AND EQUIPMENT BALANCE

BODY LIQUID COMPARTMENT

SYSTEM OF BODY LIQUIDS AND ELECTROLYTE

BODY LIQUID PHYSIOLOGY AND

EQUIPMENT BALANCE

ELECTROLYTE: SUBSTANCE OF POSITIVE OR NEGATIVE IN A LIQUID SOLUTION.

CATION: POSITIVE POWERFUL ELECTRICITY

K+, Na+, Ca++, Mg++

ANION: NEGATIVE POWERFUL ELECTROLYTE

Cl-, HCO3-, PROT, AS. ORG, HPO4-, SO4-

BODY FLUIDS

TOTAL LIQUID BODY INFLUENCE BY:

• FAT NETS

• GENDER

• AGE

• SPECIES

USE OF BODY LIQUID

AS MEDIUM REACTION IN THE BODY

EXCHANGE OF CELL AND OUTSIDE

BODY LIQUID COMPARTMENT

60% BW CONSIST OF WATER

EXAMPLE:

HORSE BB 500 KG 300L

DOG BW 20 KG 20 L

BODY LIQUID IS ENDED:

INTRA CELLULAR (CIS) 40% BB

EXTRA CELLULAR (CES) 20% BB

EXTRA CELLULAR LIQUIDS

INTERTITIAL LIQUID 15% BB

INTRA VASCULAR LIQUIDS (PLASMA) 5% BB

LIQUID TRANS-CELLULAR LIQUID GASTROINTESTINAL DUCT

ELECTROLY CONTENT

KATION ANION

CIS K+, Mg++, Na+ HPO4-, PROT-.,

HCO3-, Cl-

CES Na+, Ca++, K+,

Mg++

Cl-, HCO3-,

PROT-, As.Org-,

HPO4-, SO4-

C.INTRAVASK Na+, Ca++, K+,

Mg++

Cl-, HCO3-,

PROT-, As.Org-,

HPO4-, SO4-

BODY LICENSE BALANCE

IN OUT

Sensible Gain:

Drinks

Food

Insensible Gain:

Metabolism

Sensible Loss:

• Urine

• Feces

Insensible Loss:

• Respiratory

• Sweat

SYSTEM OF BODY LIQUIDS

AND ELECTROLYTE

1. THERMOREGULATOR

(HIPOTHALAMUS)

AND SECRETION VASOPRESIN.

2. HORMONAL

HORMON ANTIDIURETIK (ADH)

ALDOSTERON

DISORDERS OF LIGHT

BALANCE

A. INTERRUPTION VOLUME

B. OSMOLARITAS DISORDERS

C. COMPOSITION DISORDERS

D. DISTRIBUTION DISORDERS

OSMOLALITAS DAN

OSMOLARITAS

OSMOL(OSM) : OSMOTIC UNIT ACTIVITY

OSMOLARITAS IS THE TOTAL NUMBER OF

OSMOL PER LITER SOLUTION

OSMOLALITAS IS THE TOTAL NUMBER OF

OSMOL PER KILOGRAM WATER

OSMOLALITAS AND

OSMOLARITAS

ISOSMOTIK: its osmolarity is equal to

body fluids.

NaCl 0.9%, Glucose 5%, Urea 1.74%

ISOTONIK: its osmolarity is same with liquid

body and can maintain body cell volume.

NaCl 0.9%, Glucose 5%.

HYPOTHOTICS: osmolaritas lar <body fluids

NaCl 0.45%

HYPERTONIC: lar osmolaritasnya> body fluids

NaCl 1.5%

INTERRUPTION VOLUME

AND OSMOLARITYEspecially at CES, divided into:

1. Dehydration Volume

* Isotonic: diarrhea, vomiting, blood loss,

Burns.

water deficiency and NaCl.

* Hypotonic: excessive sweating.

Na deficiency

* Hypertonic: Diabetes Mellitus polyuria

INTERRUPTION VOLUME

AND OSMOLARITY

2. Overhydration / Hyperhydration:

Isotonic: Oedema

Hypotonic: excessive amount of water

giving free electrolyte infusion

Hypertonic: Na extracellular >>; because of

adrenal cortex hyperfunction

COMPOSITION DISORDERS

Occurs when there is / concentration of

one or several kinds of electrolytes in the

body fluids. Ex:

K - Hipokalemi

K - Hiperkalemi

Na - Hypernatremia

Gluc - Hypoglycemia

DISTRIBUTION DISORDERS

Stockpiling of Liquids at:

A. Pulmonary membrane Hydrothorax

B. lining Ascites Abdominal

C. Jar. Certain Udema

BALANCE ACID-BASES

Hydrogen ion concentration (H +) at CES

± 40 nmol / L, pH 7.4 (7.35-7.45)

Enzymatic reactions need optimum pH

Perub. The concentration of H + ions affects

the biological processes and metabolism in

the body

DEFINITION pH

pH is a negative logarithm of the hydrogen ion concentration.

pH = - log[H+]

When the blood hydrogen concentration increases then the pH goes down acidosis

When the blood hydrogen concentration falls then the pH rises alkalosis

ACID BASIC SETTINGS

1. BUFFER SYSTEM (BUFFER)

2. RESPECT SYSTEM

3. KIDNEY

RESERVATION SYSTEM

Fast work serves to capture or release H + so that it can minimize the concentration of hydrogen ions.

Body buffer capacity includes:

* Extracellular buffer: bicarbonate buffer and phosphate

* Intracellular buffering: proteins, organic and inorganic phosphates and in Hb.

* Bone: buffer storage area.

BIKARBONAT DISTRIBUTOR

SYSTEMSimilar buffers are most effective because of large enough quantities.

CO2+H2O H2CO3 H+ + HCO3

The Henderson-Hasselbalch Equation:

pH= pK +log [A-]

[HA]

For bikarbonat :

pH= 6,1 + log [HCO3-]

[H2CO3]

RESPIRATORY SYSTEM

• The function regulates the discharge of Co2 gas

through the lungs.

• CO2 breath fast (hyperventilation)

• CO2 slow breath (hypoventilation)

• Respiratory frequency increased due to:

• * pCO2 increases

• * blood pH down

• * pO2 decreases

RESPIRATORY SYSTEM

The Henderson-Hasselbalch Equation:

pH = 6,1 + log [HCO3- ]

0,03xpCO2

Information :

0.03 = solubility factor of CO2 in plasma

pCO2 = tek. Partial gas CO2 (= 40 mmHg)

HCO3 = 24 mEq / L

GINJAL

Fungsi : meningkatkan ekskresi H+ dan

mengatur reabsorbsi HCO3 Plasma.

Ada 2 mekanisme :

1. Pertukaran H+ dengan Na+.

2. Pertukaran NH4+ dengan Na+.

INTERFERENCE BALANCE

BALANCE

Causative factor :

1. Impaired respiratory function.

2. Impaired kidney function.

3. Abnormal acid-base addition.

4. Abnormal acid-base loss.

PEM. ACID-BASIS

INTERFERENCE LABORATORY

* Sample: ARTERI BLOOD

* Anticoagulants: HEPARIN

* Tool: BLOOD GAS ANALIZER

* Parameters:

-blood pH, normal: 7.4

-pC02, normal: 40 mmHg

-HCO3, normal: 24 mEq / L

HOW TO INTERPRETATION

The Henderson-Hasselbalch Equation:pH =

6,1 + log [HCO3-]

0,03xpCO2

pCO2 = its value is only changed by

Respiratory Factor (Respiratorik)

[HCO3] = its value is changed not because

of the Respiratory Factor (Metabolic).

COMPENSATION

* Compensation is due to the increase

the function of controlling organs to try

returns the pH of body fluids to the pH

normal .

* Compensation is done by:

- Respiratory

- Kidney

* Light Compensated

heavy Uncompensated

ASIDOSIS METABOLIK

* Indicated by a decrease in pH and

bicarbonate (pH <7.4; HCO3)

* Cause:

- Lactic acidosis, ketoacidosis. - Diarrhea

-Pharmaceuticals: salicylate, methanol, - Kidney failure

ethylene glycol, and paraldehyde.

COMPENSATION:

* Response of respiratory compensation with increased ventilation and decreased pCO2

ASIDOSIS RESPIRATORIK

* Indicated by a decrease in pH and

increased pCO2 (pH <7.4; pCO2)

* Cause: decreased effectiveness of alveolar ventilation due to:

- upper bag breath obstruction, pneumonia, pneumothorax and chronic lung obstruction.

- CNS medications eg for anesthesia and sedatives.

* COMPENSATION:

The compensatory response to renal bicarbonate retention (HCO3)

ALKALOSIS METABOLIK

* Indicated by increased pH and

bicarbonate (pH> 7.4; HCO3)

* Cause:

-Loss of excessive H + ions due to vomit; use of mineralocorticoids and diuretics.

-Recency of bicarbonate due to renal failure

-Calcalation contraction

COMPENSATION:

* Respiratory response with hypo-ventilation and increased pCO2

ALKALOSIS RESPIRATORIK

* Indicated by increasing pH and decreasing pCO2 (pH> 7.4; pCO2 )

* Cause: Hyperventilation due to hypoxia due

- pulmonary and cardiac disease (CHF).

disturbance at the center of the breath due to salicylate intoxication and infection with gram-negative bacteria.

psychological-psychological

COMPENSATION:

* Response compensation with decreased bicarbonate through resistance of renal bicarbonate reabsorbtion (HCO3 )

RANGKUMAN

INTERRU

PTION

pH PRIMARY

DISORDERS

COMPENSION

RESPONSES.

Asidosis

Metabolik

HCO3- pCO2

Alkalosis

Metabolik

HCO3- pCO2

Asidosis

Respiratorik

pCO2 HCO3-

Alkalosis

Respiratorik

pCO2 HCO3-