Fluid, electrolyte, and acid-base imbalances
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Transcript Fluid, electrolyte, and acid-base imbalances
Zoya Minasyan, RN, MSN-Edu
Purpose
Maintain a balance between acids and bases to achieve
homeostasis: State of equilibrium
Health problems lead to imbalance
Diabetes mellitus
Vomiting and diarrhea
Respiratory conditions
Chemotherapy- N/V
pH
Measure of H+ ion concentration
Blood is slightly alkaline at pH 7.35 to 7.45.
<7.35 is acidosis.
>7.45 is alkalosis.
Range of pH
Fig. 17-16. The normal range of plasma pH is 7.35 to 7.45. A normal pH is maintained by a ratio of 1 part
carbonic acid to 20 parts bicarbonate.
Regulators of Acid/Base
Metabolic processes produce acids that must be
neutralized and excreted.
Regulatory mechanisms
Buffers
Respiratory system
Renal system
Regulators of Acid/Base
Buffers: Act chemically to neutralize acids or change
strong acids to weak acids
Primary regulators
React immediately
Cannot maintain pH without adequate respiratory and
renal function
The buffers in the body include
carbonic acid–bicarbonate
monohydrogen- dihydrogen phosphate
intracellular and plasma protein
hemoglobin
Regulators of Acid/Base
Respiratory system: Eliminates CO2
Respiratory center in medulla
controls breathing.
Responds within minutes/hours to changes in acid/base.
Increased respirations lead to
increased CO2 elimination
decreased CO2 in blood.
Regulators of Acid/Base
• When released into circulation, CO2 enters RBCs and combines
with H2O to form H2CO3.
• This carbonic acid dissociates into hydrogen ions and
bicarbonate.
• The free hydrogen is buffered by hemoglobin molecules, and the
bicarbonate diffuses into the plasma.
• In the pulmonary capillaries, this process is reversed, and CO2 is
formed and excreted by the lungs.
• As a compensatory mechanism, the respiratory system acts on the
CO2 + H2O side of the reaction by altering the rate and depth of
breathing to “blow off” (through hyperventilation) or “retain”
(through hypoventilation) CO2.
• If a respiratory problem is the cause of an acid-base imbalance
(e.g., respiratory failure), the respiratory system loses its ability to
correct a pH alteration.
Regulators of Acid/Base
Renal system: Eliminates H+ and reabsorbs HCO3 Reabsorption and secretion of electrolytes (e.g., Na+, Cl)
Responds within hours to days
Regulators of Acid/Base
• The three mechanisms of acid elimination are
• secretion of small amounts of free hydrogen into the renal
tubule,
• combination of H+ with ammonia (NH3) to form ammonium
(NH4+), and
• excretion of weak acids.
• The body depends on the kidneys to excrete a portion of the
acid produced by cellular metabolism.
• Thus the kidneys normally excrete acidic urine (average pH
equals 6).
• As a compensatory mechanism, the pH of the urine can
decrease to 4 and increase to 8.
Alterations in Acid-Base Balance
Imbalances occur when compensatory mechanisms
fail.
Classification of imbalances
Respiratory: Affect carbonic acid concentration
Metabolic: Affect bicarbonate
Respiratory Acidosis
Carbonic acid excess caused by
Hypoventilation
Respiratory failure
Compensation
Kidneys conserve HCO3- and secrete H+ into urine.
Respiratory Acidosis
• Hypoventilation results in a buildup of CO2
• carbonic acid accumulates in the blood
• Carbonic acid dissociates, liberating H+, and a decrease
in pH occurs.
• If CO2 is not eliminated from the blood, acidosis results
from the accumulation of carbonic acid.
• In acute respiratory acidosis, the renal compensatory
mechanisms begin to operate within 24 hours.
Respiratory Alkalosis
Carbonic acid deficit caused by
Hyperventilation
Hypoxemia from acute pulmonary disorders
Metabolic Acidosis
Base bicarbonate deficit caused by
Ketoacidosis
Lactic acid accumulation (shock)
Severe diarrhea
Kidney disease
Metabolic acidosis (base bicarbonate deficit) occurs when
an acid other than carbonic acid accumulates in the body,
or when bicarbonate is lost from body fluids.
Compensatory mechanisms
Increased CO2 excretion by lungs
Kussmaul respirations (deep and rapid)
Kidneys excrete acid
Metabolic Alkalosis
Base bicarbonate excess caused by
Prolonged vomiting or gastric suction
Gain of HCO3 Compensatory mechanisms
Decreased respiratory rate to increase plasma CO2
Renal excretion of HCO3-
Blood Gas Values
Arterial blood gas (ABG) values provide information
about
Acid-base status
Underlying cause of imbalance
Body’s ability to regulate pH
Overall oxygen status
Interpretation of ABGs
Diagnosis in six steps:
Evaluate pH.
Analyze PaCO2.
Analyze HCO3-.
Determine if CO2 or HCO3- matches the alteration.
Decide if the body is attempting to compensate.
Normal Blood Gas Values
Table 17-15. Normal Arterial Blood Gas Values *.
Sample ABG Interpretation
Table 17-16. Arterial Blood Gas (ABG) Analysis.
Acid-Base Mnemonic—ROME
Respiratory
Opposite
Alkalosis↑ pH ↓ PaCO2
Acidosis ↓ pH ↑ PaCO2
Metabolic
Equal
Acidosis ↓ pH ↓ HCO3
Alkalosis↑ pH ↑ HCO3
Interpretation of ABGs
pH 7.18
PaCO2 38 mm Hg
PaO2 70 mm Hg
HCO3- 15 mEq/L
What is this?
Metabolic acidosis
Interpretation of ABGs
pH 7.58
PaCO2 35 mm Hg
PaO2 75 mm Hg
HCO3- 50 mEq/L
What is this?
Metabolic alkalosis
Question
A patient with an acid-base imbalance has an altered
potassium level. The nurse recognizes that the potassium
level is altered because:
1. Potassium is returned to extracellular fluid when
metabolic acidosis is corrected.
2. Hyperkalemia causes an alkalosis that results in
potassium being shifted into the cells.
3. Acidosis causes hydrogen ions in the blood to be
exchanged for potassium from the cells.
4. In alkalosis, potassium is shifted into extracellular fluid
to bind excessive bicarbonate.
24
Answer
Answer: 3
Rationale: Changes in pH (hydrogen ion concentration)
will affect potassium balance.
In acidosis,
hydrogen ions accumulate in the intracellular fluid (ICF),
and potassium shifts out of the cell to the extracellular fluid to
maintain a balance of cations across the cell membrane.
In alkalosis,
ICF levels of hydrogen diminish,
and potassium shifts into the cell.
If a deficit of H+ occurs in the extracellular fluid, potassium will shift
into the cell.
Acidosis is associated with hyperkalemia
Alkalosis is associated with hypokalemia.
Case Study 1: Jeri
Jeri’s been on a 3-day party binge.
Friends are unable to awaken her.
Assessment reveals level of consciousness difficult to
arouse.
Respiratory rate 8
Shallow breathing pattern
Diminished breath sounds
1.
2.
What ABGs do you expect?
What is your treatment?
26
Case Study 1: Jeri
What ABGs do you expect?
Respiratory acidosis reflected by pH <7.35 and PCO2 >45 mm
Hg. The HCO3 will be normal (20-30 mEq/L) if her respiratory
depression has lasted less than 24 hours; if longer than 24 hours,
the HCO3 may be elevated as the result of compensation. The
PaO2 may be <80 mm Hg because of respiratory depression
leading to hypoxemia.
2. What is your treatment?
Determine the cause of the respiratory depression. If induced by
opioids or benzodiazepines, treat with appropriate antagonists.
If induced by alcohol or other CNS depressants, breathing must
be stimulated until the effects of drugs have worn off.
Mechanical ventilation may be necessary to increase respiratory
rate and depth, increasing oxygenation and promoting excretion
of carbon dioxide.
Case Study 2: Mayna
Presented to the ED after a sexual assault
Examination reveals hysteria and emotional distress.
Respiratory rate 38
Lungs clear
1.
O2 sat 96%What ABGs do you expect?
2.
What is your treatment?
Copyright © 2011, 2007 by Mosby, Inc., an affiliate
of Elsevier Inc.
Case Study 2: Mayna
1. What ABGs do you expect?
Respiratory alkalosis indicated by pH >7.45 and PCO2
<35 mm Hg. The HCO3 will be normal (20-30 mEq/L)
because compensation will not occur in this acute
event.
2. What is your treatment?
Relieve her anxiety and coax her to take slow breaths.
Carbon dioxide may be administered by mask, or she
may be asked to breathe into a paper bag placed over
her nose and mouth.
Case Study 3: Allen
17 years old
History of
Feeling bad
Fatigue
Constant thirst
Frequent urination
Blood sugar is 484 mg/dL.
Respirations are 28 and deep.
Breath has a fruity odor.
Lungs are clear.
1.
2.
What ABGs do you expect?
What is your treatment?
Case Study 3: Allen
What ABGs do you expect?
A diabetic ketoacidosis is a metabolic acidosis indicated by
a pH <7.35 and a HCO3 <20 mEq/L. The PCO2 will be
within the normal range if the acidosis is uncompensated,
but will be <35 mm Hg if compensation has occurred. The
PaO2 will not be affected.
2. What is your treatment?
Administration of insulin to promote normal glucose
metabolism and administration of fluids and electrolytes
to replace those lost because of the hyperglycemia.
Fluid volume deficit
Can occur with
Abnormal loss of body fluids
Diarrhea, hemorrhage, polyuria
Inadequate fluid intake
Shift of fluid from plasma into interstitial space
• Treatment
Correct the underlining cause
Replace the fluid and electrolyte (LR or NS isotonic solutions)
Fluid volume excess
May result from
excessive intake of fluid
Abnormal retention of fluids(heart failure, renal failure)
Shift of fluid from interstitial fluid into plasma fluid
o Collaborative care
o
o
o
ID primary cause
Diuretics and fluid restriction
Restriction of Na intake
Fluid excess may result to ascites or pleural effusion, and
paracentesisi or thoracentsis may be necessary.
Commonly prescribed crystalloid solutions
Dextrose in water
5% isotonic
10% hypertonic
Saline
0.45% hypotonic
0.9% isotonic
3.0% hypertonic
Dextrose in Saline
5% in 0.225% isotonic
5% in 0.45% hypertonic
5% in 0.9% hypertonic
Multiple Electrolyte Solutions
Ringer’s solution- isotonic, includes CL, Na, K, Ca
Lactated Ringer’s solution- isotonic-Na, K, Cl, Ca, and
lactate(the precursor of bicarbonate)
CVADs
Catheters placed in large blood vessels of people who
require frequent access to the vascular system
Subclavian vein, jugular vein
Three different methods
Centrally inserted catheter(by MD)
Peripherally inserted central catheter
Implanted ports( by MD)
CVADs
Permit frequent, continuous, rapid, or intermittent
administration or monitoring
Indicated for patients with limited peripheral vascular
access or need for long-term vascular access
Centrally Inserted Catheter
Inserted into a vein in the neck, chest, or groin with tip
resting in the distal end of the superior vena cava
Single, double, triple, or quad lumen
Nontunneled or tunneled
Central .Venous Catheter
PICC
Central venous catheters inserted into a vein in the
arm
Single or multilumen, nontunneled
For patients who need vascular access for 1 week to 6
months
Complications include catheter occlusion and
phlebitis.
Copyright © 2011, 2007, 2004, 2000, 1996, 1992,
1987, 1983 by Mosby, Inc., an affiliate of Elsevier
Inc.
PICC
Implanted Infusion Ports
Central venous catheter connected to an
implanted, single or double subcutaneous injection
port
Port is metal sheath with self-sealing silicone
septum.
Implanted Infusion Port
Implanted Infusion Port
Port accessed with special Huber-point needle
Advantages
Good for long-term therapy
Low risk of infection
Cosmetic discretion
Care requires regular flushing.
Complication: (table 17-21 page 330)
Cath occlusion(kinked, precipitate build up)
Embolism( dislodgment of thrombus, air entry, cath
breaking)
Cath related infection
Cath Migration
Nursing Management
Inspect catheter and insertion site.
Assess pain.
Change dressing and clean according to institution policies.
Change injection caps.
Flushing is important.
• Catheter and insertion site assessments include inspection of the
site for redness, edema, warmth, drainage, and tenderness or pain.
Observation of the catheter for misplacement or slippage is
important.
• Transparent dressing or gauze may be used.
• Discuss cleaning techniques with chlorhexidine-based
preparations, povidone-iodine, and isopropyl alcohol
• Teach the patient to turn the head to the opposite side of the
CVAD insertion site during cap change.
• Flushing: Use a normal saline solution in a syringe that has a
barrel capacity of 10 mL or more to avoid excess pressure on the
catheter. If resistance is felt, force should not be applied.
Removing CVADs
Should be done according to policy and procedures.
Gently withdraw.
Apply pressure.
Ensure that catheter tip is intact.