Chapter 8 Disorders of Fluid, Electrolytes and Acid-Base Balance - Summer 2024 PDF

Summary

These lecture notes cover Chapter 8, titled "Disorders of Fluid, Electrolytes, and Acid-Base Balance". The content details fluid compartments, diffusion, osmosis, osmolarity, tonicity, and various types of fluid imbalances, along with their clinical manifestations. This is focused on medical physiology and pathophysiology.

Full Transcript

Chapter 8
Disorders of Fluid,
Electrolytes and Acid-Base
Balance
Dr. Kelly Goebel DNP, ACNP-BC
Distribution of Body Fluid
Water is found in three different fluid compartments:
Intracellular fluid (ICF)= 2/3rd
Extracellular fluid (ECF)= 1/3rd
Diffusion and Osmosis
Diffusion: movement of particles along a concentration gradient.
Osmosis: movement of water across a semipermeable membrane.

Urine specific gravity compares weight or urine to water- reflects the kidneys’ ability to produce a
concentrated or diluted urine based on serum osmolality and the need for water conservation or
excretion.
Osmolarity & Tonicity

Osmolarity Tonicity
The number of osmoles of solute per liter of The effect that the osmotic pressure within a
solution; dependent on the number of particles solution exerts on cell size because of water across
suspended in a solution. the cell membrane.
Fluid status maintained by: osmoreceptors, Describes intravenous fluid solutions (three types)
sensation of thirst, RAAS, ADH, natriuretic Isotonic: same tonicity as blood; 0.9% NaCl.
hormones Cells do not shrink or swell.
Hypotonic: less tonicity than blood; 0.45%
NaCl. Water moves into the cell and cells
swell.
Hypertonic: greater tonicity than blood; 3%
NaCl. Water is pulled out of the cell and cells
shrink.
Pathophysiol
ogy of F & E
Imbalance
Edema
Palpable swelling produced by expansion of the interstitial fluid volume (can hole 10-30L of fluid)
Patho
Increase capillary filtration pressure
Decrease capillary osmotic pressure
Increase capillary permeability**
Produce obstruction to lymph flow
Localized or generalized
Anasarca: generalized body edema
Dependent edema
Third space (peritoneum, pleural cavity)
 Increased Capillary Decreased Colloidal Increased Capillary Obstruction of
Pressure Osmotic Pressure Permeability Lymphatic Flow
Increased vascular Increased loss of Inflammation Surgical removal of
volume (Heart plasma protein Allergic reaction lymph nodes
failure, kidney (kidney disease, Tissue injury/burns
disease) burn)
Decreased
production of
protein
(malnutrition)
See next slide-
Albumin
Albumin
Albumin: smallest of plasma proteins
Low albumin (hypoalbuminemia) in the bloodstream causes low oncotic pressure-> results in
edema
Edema due to decreased colloidal osmotic pressure usually result of loss of albumin-> liver
failure-> impaired synthesis of albumin
Sodium and Water Balance
Effective circulating volume is the major regulator
Low effective circulating volume-> activates feedback mechanisms that produce an increase in renal
sodium and water retention
High effective circulating volume-> triggers feedback mechanisms that decrease sodium and water
retention
Baroreceptors
RAAS
Thirst-> regulator of water intake (polydipsia vs. hypodipsia)
Antidiuretic hormone (ADH)-> regulator of water output (SIADH vs. DI)- we will cover this under endocrine
disorders
Isotonic Fluid Volume Deficit
Decrease in ECF/circulating blood volume Clinical manifestations:
Proportionate losses in sodium and water Acute weight loss
Etiology: Decreased urine output
Increased osmolality and specific gravity
Inadequate fluid intake: Therapeutic
withholding, unconscious, impaired thirst Thirst
Excessive GI loss: V/D, osmotic diuresis, Increased BUN/Creatinine
adrenal insufficiency Hypotension, tachycardia, shock
Excessive skin loss: Fever, burns Thready pulse
Third-space loss: Edema, ascites Sunken eyes
Isotonic Fluid Volume Excess
Expansion of the ECF compartment with increased Clinical Manifestations:
interstitial and vascular volume Acute weight gain
Compensatory vs. Pathologic Edema
Etiology: Full, bounding pulse
Inadequate sodium and water elimination Venous distension
Congestive heart failure, renal failure, Pulmonary Edema (SOB, crackles, dyspnea,
Cushing disease, liver failure cough)
Excessive sodium intake in r/t output
Excessive dietary intake
Ingestion of sodium containing
medications
Excessive fluid intake in relation to output
Administration of parenteral fluids or blood at
an excessive rate
Sodium Imbalance
Serum osmolality (275-295 mOsm/kg) changes with plasma sodium concentration (135-145
mEq/L)
Common electrolyte disorder Hypertonic
Age-related events contribute (Translocational)
Hypertonic or Hypertonic State

Osmotic shift of
water from ICF
to ECF

Ex.
Hyperglycemia
(serum os > 280)
 Hypovolemic:
Water + Sodium
lost

Hypotonic
(Dilutional)
Hyponatremi
a r/t water
dilution
Hypervolemic: Euvolemic:
Edema-associated Retention of water
disorders, increased with dilution of
ADH sodium
Hyponatremia < 135 mEq/L

Hypovolemic hypotonic hyponatremia (decreased serum Hypervolemic hyponatremia (decreased serum sodium with
sodium with decreased ECF volume) increased ECF volume)
Sweating Hyponatremia + edema
GI irrigations with distilled water Decompensated CHF
Advanced liver disease
GI losses
Kidney failure
Diuretic use
Clinical Manifestations largely r/t sodium dilution
Normovolemic (Euvolemia) hyponatremia (decreased
serum sodium with normal ECF) N/V

Retention of water with dilution of sodium (ECF WNL) Serum osmolality decreased
Increased ADH levels Cellular swelling-> coma, headache (neuro), abdominal
Syndrome of inappropriate antidiuretic cramps
hormone (SIADH)
Trauma
Hypernatremia > 145 mEq/L
(Serum osmolality > 295 mOsm/kg)
Patho Clinical Manifestations
Water lost in excess of sodium Tachycardia
Causes cellular dehydration Polydipsia
Oliguria
Etiology
High specific gravity
Excessive water loss (diarrhea, sweating,
tachypnea, DI) Dry mucous membranes
Decreased water intake (inability to swallow, Headache, agitation
unresponsive) Seizures, coma
Excessive sodium intake (near drowning in salt Weak, thready pulse (vascular depletion)
water) Increased BUN/Creat

Cerebral edema ensues if water replacement
proceeds at a rate that does not allow for excretion
or metabolism of accumulated solutes
Hyperkalemia
Pathophysiology
Potassium regulates:
Excitability of cardiac, skeletal and muscle
Maintains acid-base balance
Nerve impulse conduction
Potassium regulation
1. Renal mechanisms (aldosterone)
2. Extracellular-Intracellular shifts
Hypokalemia < 3.5 mEq/L
Decrease in plasma potassium levels Clinical Manifestations
Etiology Cardiac arrhythmias
Inadequate intake (diet) Muscle cramps, paralysis
Excessive renal loss (potassium sparing Confusion
diuretics, corticosteroids)
Metabolic alkalosis
GI loss (V/D, suction)
ECG: Depression of ST segment, U wave
Transcompartmental Shift
Albuterol, administration of insulin for
DKA, metabolic/respiratory alkalosis
Hyperkalemia > 5.2 mEq/L
Increase in plasma levels of potassium Etiology
Seldom occurs in healthy people 1. Decreased renal elimination (renal failure,
ACE-I)
2. Excessive rapid administration (PO,
supplements)
3. Transcellular shift from ICF to ECF (acidosis,
crush injuries)
Clinical Manifestations
Paresthesia
Diarrhea
ECG: widened QRS complex, peaked T waves
Cardiac arrest
Metabolic acidosis
Mechanisms Regulating Calcium,
Phosphorus and Magnesium Balance
Vitamin D facilitates the absorption of calcium from the gastrointestinal tract into the
bloodstream
Parathyroid Hormone (parathyroid disorders covered in endocrine lecture)
Calcium and phosphorus are the major mineral contents of bone
Ingested in diet, absorbed from intestine, filtered in kidney, eliminated in urine.
There is a reciprocal relationship between calcium and phosphate;
Increased calcium in the blood: decrease in phosphate
Decreased calcium in the blood: increase in phosphate
Calcium Imbalances

Hypocalcemia < 8.5 mg/dL Hypercalcemia > 10.5 mg/dL
Etiology: malabsorption, vitamin D deficiency, Decreased neuromuscular excitability
renal failure, transfusion of citrated blood, Etiology: increased bone resorption secondary
hypoparathyroidism to neoplasm or immobilization, thiazide
Increased neuromuscular excitability diuretics, excessive intake
Clinical Manifestations: Clinical manifestations:
Laryngeal spasm Muscle weakness, ataxia
Tetany Coma, lethargy
Ventricular dysrhythmias Hyperreflexia
Chvostek’s sign; facial spasm Flank pain/kidney stones
Trousseau’s sign; carpal spasm Osteoporosis
Bone pain (chronic) N/V
Phosphate Imbalances

Hypophosphatemia < 2.5 mg/dL Hyperphosphatemia > 4.5 mg/dL
Etiology: Decreased absorption, antacid use, Etiology: renal failure, massive trauma,
increased renal loss, alcoholism, hypoparathyroidism
hyperparathyroidism Clinical Manifestations:
Clinical Manifestations: Paresthesia
Intentional tremor Tetany
Hyporeflexia Cardiac dysrhythmias
Seizures Reciprocal calcium change: hypocalcemia
Reciprocal calcium change:
hypercalcemia
Magnesium Imbalances

Hypomagnesemia < 1.8 mg/dL Hypermagnesemia > 3.0 mg/dL
Etiology: Etiology: renal failure, magnesium
Malabsorption/Malnutrition laxatives/antacids, pre-eclampsia
Increased renal excretion of magnesium Clinical Manifestations:
Chronic alcoholism Hyporeflexia
Clinical Manifestations: Severe > 12
Tetany, + Babinski Calcium-channel blocking effects:
Nystagmus cardiac arrest
Cardiac dysrhythmias Respiratory muscle paralysis
 Chapter 8
Acid-Base
Imbalances
Regulation of pH
1. Chemical buffer systems
2. Respiratory control mechanisms
3. Renal control mechanisms
Respiratory Control Mechanisms
Chemoreceptors in blood vessels responsive to C02 in blood
Increased ventilation decreases PC0₂
Decreased ventilation increases PC0₂
Control of pH is rapid/within minutes and maximal within 12-24 hours
Renal Control Mechanisms

Excretes H⁺

Reabsorption of HC0₃

Production of new HC0₃
Laboratory Results

Base
Carbon Bicarbonate
Excess/Defici
Dioxide Levels
t
 Arterial Blood Gases
The pressure of the gases in the bloodstream
Pac02: the pressure of carbon dioxide in arterial blood (35 to 45 mm Hg)
HC0₃: the amount of bicarbonate ion in the blood (22-26 mEq/L)
pH: 7.35-7.45 (7.40)
Don’t forget about the oxygen!
Metabolic vs. Respiratory Acid Base
Disorders
Metabolic disorders produce an alteration in Respiratory disorders involve an alteration in
plasma HC0₃ the PC0₂
Metabolic acidosis: elevation in pH Respiratory acidosis: decrease in pH
because of decrease in HC0₃ (decrease in ventilation and increase in
Metabolic alkalosis: elevation in pH PC0₂)
because of increased HC0₃ Respiratory alkalosis: increase in pH
(increase in alveolar ventilation and
decrease in PC0₂)
ACID BASE IMBALANCE
When the lungs or kidneys fail to
maintain acid-base balance-> Any of
the four Acid-Base Imbalances can
occur:
1. Respiratory acidosis
2. Respiratory alkalosis
3. Metabolic acidosis
4. Metabolic alkalosis
Respiratory Acidosis
Accumulation of PC0₂ (hypercapnia) from impaired ventilation (acute or chronic)
Etiology: Respiratory/Airway issues
Lung disease: COPD, pneumonia
Depression of respiratory center: Drug overdose, head injury
Airway obstruction: Chest injuries, extreme obesity, paralysis of respiratory muscles
Clinical manifestations: Headache (cerebral vasodilation), confusion, stupor/coma
Serum pH is < 7.35
Pc02 > 45 mm Hg
Respiratory Alkalosis
Decrease in PC02 (Hypocapnia) caused by hyperventilation
Etiology: Anxiety, hypoxia, pain, fever, salicylate intoxication
Clinical manifestations: Dizziness (cerebral vasoconstriction), numbness/tingling of fingers, panic,
muscle spasms
Serum pH > 7.45
Pc02 < 35 mm Hg
Metabolic Acidosis
Excess acids OR abnormal loss of bicarbonate
Etiology: Lactic acidosis, ketoacidosis, diarrhea, chronic kidney disease
Clinical manifestations: Kussmaul breathing (deep rapid respirations- compensatory), coma,
dysrhythmias, hypotension
Serum pH < 7.35
Serum HC03 < 22 mEq/L

Metabolic acidosis causes H+ to enter cells replacing potassium-> causes hyperkalemia
Metabolic Alkalosis
Primary excess of bicarbonate (HC0₃)
Etiology: Excess bicarb ingestion, vomiting of excess gastric acid, gastric suction
Clinical manifestations: asymptomatic, volume depletion, confusion, hypotension, decreased
rate/depth of respirations (compensatory)
Serum pH > 7.45
Serum HC03 >26 mEq/L

Metabolic alkalosis causes potassium to enter the cell-> hypokalemia
 *Metabolic acidosis
causes H+ to enter cells
& potassium to exit the
cell -> causes
hyperkalemia
*Metabolic alkalosis
causes H+ to exit the
cells & potassium to
enter the
cell-> hypokalemia
Abnormality pH PaC0₂ Hc0₃
Respiratory Acidosis ↓ ↑ Normal

Respiratory Alkalosis ↑ ↓ Normal

Metabolic Acidosis ↓ Normal ↓

Metabolic Alkalosis ↑ Normal ↑