Fluids and Electrolytes, Acids and Bases
Water Balance
Total body water (TBW)
– Intracellular fluid
– Extracellular fluid:
o Interstitial fluid
o Intravascular fluid
o Lymph, synovial, intestinal, CSF, sweat,
urine, pleural, peritoneal, pericardial,
and intraocular fluids
Age-Related Considerations
Children
– More susceptible to changes in body fluids
– Greater body surface area 
Elderly
– Decreased % total body water
– Increased adipose tissue and decreased muscle mass
– Diminished thirst perception
– Decline in renal function
Water Balance- Regulation
Mechanisms
– ADH
o Increases when person is dehydrated leading to water retention
– Thirst sensation
– Osmoreceptors (hypothalamus)
o Stimulated by hyperosmolality and plasma volume depletion
– Baroreceptors (blood vessels):
o Stimulated by high blood pressure (hypervolemia)
Water Movement Between Fluid Compartments 
Forces favoring filtration:
– Capillary hydrostatic pressure (blood pressure)
– Interstitial oncotic pressure (water-pulling)
Forces favoring reabsorption:
– Plasma oncotic pressure (water-pulling)
– Interstitial hydrostatic pressure
Starling hypothesis
– Net filtration = [Forces favoring filtration] – [Forces opposing filtration]
Edema
Accumulation of fluid within the interstitial spaces
May be generalized OR organ specific 
Causes:
Increase in capillary hydrostatic pressure
Decrease in plasma oncotic pressure
Increase in capillary permeability
Lymph obstruction (lymphedema)
Types
Pitting:
– Pregnancy
– Heart failure
Non pitting edema:
– Lymphedema (due to lymphatic obstruction)
– Note: Pretibial myxedema is not edema!
Sodium and Chloride Balance
Sodium
Primary ECF cation
Regulates osmotic forces, thus water
Functions:
– Neuromuscular excitability
– Acid-base balance
– Cellular chemical reactions
– Membrane transport
Chloride
– Primary ECF anion
– Functions
o Electroneutrality
Regulation:
– Renin-angiotensin-aldosterone system (RAAS)
o Aldosterone leads to:
• Sodium and water reabsorption
• Potassium and hydrogen secretion (loss in urine)
– Natriuretic peptides
Hyponatremia
Serum sodium level <135 mEq/L
Cause plasma hypo-osmolality and cellular swelling
– Decreases the ECF osmotic pressure, so water moves into the cell via osmosis
Causes:
Pure sodium loss
– Occurs through body processes such as sweat
Low intake
Dilutional hyponatremia
Effects:
Lethargy, confusion, decreased reflexes, seizures, and coma
Hypovolemia, hypotension, tachycardia
Dilutional hyponatremia is associated with weight gain, edema, ascites, and jugular vein distention
Hypernatremia
Serum sodium >147 mmol/L
Related to sodium gain or water loss
Causes:
Water movement from the ICF to the ECF
Administration of hyperosmolar solutions
Effects:
Intracellular dehydration, convulsions
Pulmonary edema
Hypertension
Hypochloremia
Usually the result of hyponatremia or elevated bicarbonate concentration
Develops as a result of vomiting and the loss of HCl
Observed in cystic fibrosis
Alters acid-base balance
Hypokalemia
Potassium level <3.5 mmol/L
Causes:
Shift of K+ from ECF into ICF:
– Insulin
o E.g. Hyperglycemic patients receiving Insulin require fluid containing potassium to accommodate for the shift that occurs as potassium moves into cells
– B2 agonists 
Increased renal excretion:
– E.g. hyperaldosteronism
Effects:
Skeletal muscle weakness
Smooth muscle atony
ECG changes
Hyperkalemia
Potassium level >5.5 mmol/L
Rare because of efficient renal excretion
Causes:
Shift of K+ from ICF into ECF:
– Insulin deficiency
o E.g. diabetic ketoacidosis
– Acidosis
– Massive cell destruction (tumor lysis syndrome)
– Decreased renal excretion
Tissue trauma, crush injury
Potassium-sparing diuretics
Effects:
Dysrhythmias
Cardiac arrest during diastole
Calcium & Phosphate
Calcium:
99% of stores are located in bone and 10% in serum
– Of the 10% in serum, 50% is ionized and 50% is complexed with albumin (40%) or inorganic elements (10%), such as phosphate
Functions:
– Bone & teeth integrity
– Blood clotting
– Hormone secretion
– Cell receptor function
– Plasma membrane stability
– Transmission of nerve impulses
– Muscle contraction
Phosphate:
Similar to calcium, most phosphate is also located in the bone
Functions:
– Bone integrity
– High-energy bonds located in ATP
– Creatine phosphate
– Acts as an anion buffer
Regulation
Calcium and phosphate concentrations are rigidly controlled
– Ca+2 x HPO4– = K(constant)
– If the concentration of one increases the other decreases;
o I.e. If phosphate level increases, calcium absorption from gut decreases
Serum Ca+2 : 8.8-10.5 mg/dL
Serum PO4– : 2.5 to 4.5 mg/dL
Hypercalcemia
Causes
Hyperparathyroidism
Malignancy
Sarcoidosis
Excess vitamin D
Effects
Nonspecific symptoms including:
– Fatigue
– Weakness
– Lethargy
– Anorexia
– Nausea and/or vomiting
Renal stones, polyuria, renal failure
Bone pain
Dysrhythmias, with potential for cardiac arrest during systole
Hypocalcemia
Causes
PTH deficiency
Vitamin D deficiency
Inadequate intestinal absorption
Bone/ tissue deposition of Ca
Effects
Increased neuromuscular excitability
Tingling and/or muscle spasm occurring in the hands, feet, and/or facial muscles
– Muscle spasms may also manifest as intestinal cramping, hyperactive bowel
sounds
Tetany:
– Carpopedal spams
Acid-Base Imbalances
Normal arterial blood pH
– 7.35 to 7.45
– Obtained by arterial blood gas (ABG) sampling
o Venous blood gas (VBG) sampling is also used, however, the reference ranges differ
o VBGs are often used for initial testing to rule out respiratory conditions and complications (e.g. in the emergency departments), as both registered nurses and laboratory technicians can collect venous blood samples when a Physician is unavailable
Acidosis
– Systemic increase in H+ concentration or decrease in bicarbonate
Alkalosis
– Systemic decrease in H+ concentration or increase in bicarbonate
Acid-Base Balance: Basic facts
Acid-base balance: Careful regulation to maintain a normal pH
pH: inverse logarithm of the H+ concentration
– When H+ is high in number, pH is low (acidic);
– When H+ is low, pH is high (alkaline)
pH scale: Logarithmic scale ranging from 0 -14 whereby 0 is very acidic, 14 is very alkaline
– Each number represents a factor of 10
– I.e. If a solution moves from a pH of 6 to a pH of 5, the number H+ have increased 10 times (the solution is 10 times more acidic)
Sources of acids
– End products of protein, carbohydrate, and fat metabolism
To maintain normal pH (7.35-7.45), excess H+ is neutralized or excreted
Two major organs are involved in the regulation of acid and base balance:
1. Lungs
2. Kidneys
Body acids exist in two forms:
1. Volatile
o H2CO3 (can be eliminated as CO2 gas)
2. Nonvolatile
o Sulfuric, phosphoric, and other organic acids
o Eliminated by the renal tubules with the regulation of HCO3–
Buffering Systems
A buffer is a chemical that can bind excessive H+ or OH– without a significant change in pH
A buffering pair consists of a weak acid and its conjugate base
The most important plasma buffering system is the carbonic acid-bicarbonate system
– CO2+ H2O ↔ H2CO3 ↔ H+ + HCO3-
Carbonic Acid-Bicarbonate System 
Operates in lungs and kidneys
The greater the PCO2, the more H2CO3 is formed
– At pH of 7.4 (normal), the ratio of HCO3 to H2CO3 is 20:1
– HCO3 and H2CO3 can increase or decrease, but ratio must be maintained to maintain normal pH required for body function
For example, if HCO3 decreases, pH decreases →
(acidosis)
– pH can be returned to normal if carbonic acid also decreases
– This type of pH adjustment is referred to as compensation
Respiratory system compensates by increasing ventilation to expire CO2 or by decreasing ventilation to retain CO2
Renal system compensates by producing acidic or alkaline urine
Other Buffering Systems
Protein buffering (hemoglobin)
Proteins have negative charges, so can serve as buffers for H+
Renal buffering
Secretion of H+ in the urine and reabsorption of HCO3–
Ion exchange (between ICF and ECF)
Exchange of K+ for H+ (through Na/K balance, Na/H balance) in acidosis and alkalosis
Acidosis and Alkalosis
Four categories of acid-base imbalances:
1. Respiratory acidosis 
o Elevation of pCO2 as a result of hypoventilation
2. Respiratory alkalosis
o Depression of pCO2 as a result of hyperventilation
3. Metabolic acidosis
o Depression of HCO3– or an increase in non-carbonic acids
4. Metabolic alkalosis
o Elevation of HCO3– usually caused by an excessive loss of metabolic acids
Anion Gap
DifferenceCalculated measure of the difference between cations and anions in plasma or urine
A calculated parameter
Used cautiously to distinguish different types of metabolic acidosis
Normal anion gap = <12 mmol/L
– By rule, the concentration of anions (–) should equal the concentration of cations (+), but not all anions are routinely measured
The anion gap increases in acidosis
– Acidotic conditions can be remembered by the acronym MUD PILES CAT
