Acid Base Balance Ana Corona MSN FNPC Nursing
Acid Base Balance Ana Corona, MSN, FNP-C Nursing Instructor September 2007
Definitions l Acidosis (acidemia) occurs when p. H drops below 7. 35 l Alkalosis (alkalemia) occurs when the p. H rises above 7. 45 l A primary respiratory problem is determined if the Pa. C 02 is less than 35 mm. Hg(alkalosis) or greater than 45 mm. Hg(acidosis). l A primary metabolic problem is when the HC 03 is less than 22 m. Eq/L (acidosis) or greater than 26 m. Eq/L(alkalosis).
Metabolic Acidosis Clinical Manifestations l hyperkalemia: shift of acid to ICF and K+ to the ECF l anorexia, nausea, and vomiting l warm, flushed skin l cardiac dysrhythmias & CNS dysfunction l headache, diarrhea, tremors
Metabolic Acidosis: Etiology l Loss of base: such as in cases of severe diarrhea or Gain of metabolic acids: Anaerobic metabolism; Drug overdose (e. g. salicylates); Renal failure; Diabetic ketoacidosis l Decreased blood p. H; decreased HCO 3 normal Pa. CO 2 or decreased if compensation is occurring. l l
Metabolic Acidosis Nursing Intervention l l Assess the clinical symptoms, health history, and lab results. Identify the underlying cause to intervene appropriately. When there is severe acidosis (p. H < 7. 1), sodium bicarbonate is necessary to bring the p. H to a safe level. Correct the sodium and water deficits, as well.
Metabolic Alkalosis Clinical Manifestations l cardiac dysrhythmias; seizures; confusion; muscle twitching, agitation l >p. H; >HC 03; normal Pa. Co 2 or elevated if compensation occurs
Metabolic Alkalosis: Etiology l Loss of metabolic acids: such as in cases of prolonged vomiting or gastrointestinal suctioning. Hyperaldosteronism can cause sodium retention and loss of hydrogen ions and potassium. or Gain of Base: an increased intake of bicarbonate. Diuretics (e. g. Lasix) can cause sodium, potassium, and chloride excretion more than bicarbonate excretion.
Metabolic Alkalosis l l l Increased blood p. H increased HCO 3 normal Pa. CO 2 or elevated if compensation is occurring.
Metabolic Alkalosis Nursing Intervention l l l Assess the clinical symptoms, health history, and lab results. Identify the underlying cause to intervene appropriately. If potassium levels are decreased administer potassium as ordered per physician. If acid-base disturbance is due to hypochloremic alkalosis with volume depletion, administer a sodium chloride IV solution. If the condition is caused by hyperaldosteronism, administer potassium.
Respiratory Acidosis Clinical Manifestations l > Pa. Co 2; HCO 3 is normal or > with renal compensation l vasodilatation; cardiac dysrhythmias, tachycardia, somnolence, decreased ventilation
Respiratory Acidosis etiology l Carbon dioxide is retained when ventilation is depressed; therefore, leading to acidosis and hypercapnia (excess Pa. CO 2). l Decreased blood p. H Increased Pa. CO 2 Normal HCO 3 or elevated if compensation is occurring. l l
Respiratory Acidosis Nursing Intervention l l l Assess the clinical symptoms, health history, and lab results. Identify the underlying cause to intervene appropriately. Restore alveolar ventilation (this will remove excess CO 2), and if spontaneous ventilation is compromised (e. g. due to drug overdose or neuromuscular disorders) provide mechanical ventilation.
Respiratory Acidosis Nursing Intervention l l l Monitor the p. H, Pa. CO 2, Pa. O 2, and HCO 3 very closely. A rapid decline of the Pa. CO 2 can lead to respiratory alkalosis with seizures and death. Check for hypoxemia and hypercapnia when administering oxygen. Oxygen can work as a respiratory depressant when the person's respiratory center is no longer stimulated by a low p. H and elevated Pa. CO 2. Renal buffering generally corrects an uncomplicated chronic respiratory acidosis.
Respiratory Alkalosis Clinical Manifestations l > p. H; < Pa. C 02; HCO 3 normal or low due to compensation l nausea, vomiting, tingling of fingers
Respiratory Alkalosis Etiology l l Occurs when there is alveolar hyperventilation and a decrease in Pa. CO 2 (hypocapnia). Hypoxemia (caused by pulmonary disease, high altitudes, or congestive heart failure), hypermetabolic conditions (fever or anemia), gram-negative sepsis, hysteria, or cirrhosis of the liver can stimulate hyperventilation.
Respiratory Alkalosis l l l Increased blood p. H Decreased Pa. CO 2 Normal HCO 3 or decreased if compensation is occurring.
Respiratory Alkalosis Nursing Interventions l l Assess the clinical symptoms, health history, and lab results. Identify the underlying cause to intervene appropriately. Correct the hypoxemia and reverse the hypermetabolic states if present. Correct symptoms from hysterical hyperventilation by rebreathing from a paper bag (increases Pa. CO 2).
Basic Questions l There are three critical questions to keep in mind when attempting to interpret arterial blood gases (ABGs). First Question: Does the patient exhibit acidosis or alkalosis? Second Question: What is the primary problem? Metabolic? or Respiratory? Third Question: Is the patient exhibiting a compensatory state? In order to understand ABG analysis and remember what is abnormal, you need to review what is normal.
Remember Definitions l Acidosis (acidemia) occurs when p. H drops below 7. 35 l Alkalosis (alkalemia) occurs when the p. H rises above 7. 45 A primary respiratory problem is determined if the Pa. C 02 is less than 35 mm. Hg (alkalosis) or greater than 45 mm. Hg (acidosis). l l A primary metabolic problem is when the HC 03 is less than 22 m. Eq/L (acidosis) or greater than 26 m. Eq/L (alkalosis).
Assessment Step 1 l Step One: Determine the acid/base status of the arterial blood. Keep in mind what is Normal If the blood's p. H is less than 7. 35 this is an acidosis, and if it is greater than 7. 45 this is an alkalosis. You may hear nurses or doctors say: "The patient is 'acidotic' or 'alkalotic'
Assessment Step 2 l Once you have determined the p. H, you can move on to determine the 'primary' problem, or which system, respiratory or metabolic is the prime messenger.
Respiratory System l l Carbon Dioxide acts as the ‘acid’ of the human body, you will be able to determine if the primary acid-base imbalance is respiratory. Chemically speaking, there is an equilibrium between carbonic acid and bicarbonate. Therefore, just remember that an increased Pa. CO 2 (>45 mm. Hg) along with an acidosis (p. H < 7. 35) represents a RESPIRATORY ACIDOSIS. If you have a situation where there is a decreased Pa. CO 2 (less than 35 mm. Hg) and an alkalosis (p. H greater than 7. 45) you will have a RESPIRATORY ALKALOSIS! Easy. Right?
Metabolic System l l Keep in mind that HCO 3 represents a ‘base’ situation, and if there is an increased HCO 3 (greater than 26 m. Eq/L) in an alkalotic environment (p. H greater than 7. 45) there is a METABOLIC ALKALOSIS. On the opposite side of the coin, if there is a decreased HCO 3 (less than 22 m. Eq/L) in an acidic environment (p. H less than 7. 35) this will be representative of METABOLIC ACIDOSIS.
Compensation l l Our bodies have compensatory mechanisms that assist us to return to a state of homeostasis (equilibrium). The body attempts to compensate for whatever the primary problem is in an effort to return the acid-base balance to normal.
An illustration of COMPENSATION is given below: l l l A newly diagnosed Type 1 diabetic client has a ‘primary’ problem of metabolic acidosis (p. H 7. 29; HCO 3 16 m. Eq/L) due to an increase in ketone bodies (ketoacidosis). The nurse notes that the ABGs show a below normal Pa. CO 2 value (27 mm. Hg) and the client is breathing faster in an attempt to ‘blow off’ the carbon dioxide (CO 2: ’acid’) to create a respiratory alkalosis, the opposite of metabolic acidosis! Hint! In order to recognize ‘compensation’ look for a change in the buffering system that was not involved in the ‘primary’ problem.
Review the three essential steps of ABG analysis l Number One: Determine if the client is demonstrating an acidotic (remember: p. H less than 7. 35) or alkalotic (p. H greater than 7. 45). l Number Two: l What is the 'primary problem? l If the client is acidotic with a Pa. C 02 greater than 45 mm. Hg it is RESPIRATORY l If the client is acidotic with a HC 03 less than 22 m. Eq/L it is METABOLIC! l If the client is alkalotic with a Pa. C 02 less than 35 mm. Hg it is RESPIRATORY! l If the client is alkalotic with a HC 03 greater than 26 m. Eq/L it is METABOLIC!
l Number Three: Is the client compensating? l Are both components (HCO 3 and Pa. CO 2) shifting in the same direction? Up or down the continuum? Above or below the normal ranges? If this is noted, you know that the client’s buffering systems are functioning and are trying to bring the acid-base balance back to normal. l l l
Case Study 1 A client recovering from surgery in the post-anesthesia care unit is difficult to arouse two hours following surgery. The nurse in the PACU has been administering Morphine Sulfate intravenously to the client for complaints of post-surgical pain. The client’s respiratory rate is 7 per minute and demonstrates shallow breathing. The patient does not respond to any stimuli! The nurse assesses the ABCs (remember Airway, Breathing, Circulation!) and obtains ABGs STAT! The STAT results come back from the laboratory and show: p. H = 7. 15 Pa C 02 = 68 mm. Hg HC 03 = 22 m. Eq/L Compensated Respiratory Acidosis 2. Uncompensated Metabolic Acidosis 3. Compensated Metabolic Alkalosis 4. Uncompensated Respiratory Acidosis 1.
Answer The answer is #1 uncompensated respiratory acidosis l
Case Study 2 l An infant, three weeks old, is admitted to the Emergency Room. The mother reports that the infant has been irritable, difficult to breastfeed and has had diarrhea for the past 4 days. The infant’s respiratory rate is elevated and the fontanels are sunken. The Emergency Room physician orders ABGs after assessing the ABCs. l The results from the ABGs come back from the laboratory and show: p. H = 7. 37 Pa C 02 = 29 mm. Hg HC 03 = 17 m. Eq/L 1. Compensated Respiratory Alkalosis 2. Uncompensated Metabolic Acidosis 3 Compensated Metabolic Acidosis 4 Uncompensated Respiratory Acidosis
Answer l l Answer is #3 Compensated Metabolic Acidosis
Case Study 3 l l 1. 2. 3. 4. A client, 5 days post-abdominal surgery, has a nasogastric tube. The nurse notes that the nasogastric tube (NGT) is draining a large amount (900 cc in 2 hours) of coffee ground secretions. The client is not oriented to person, place, or time. The nurse contacts the attending physician and STAT ABGs are ordered. The results from the ABGs come back from the laboratory and show: p. H = 7. 52 Pa C 02 = 35 mm. Hg HC 03 = 29 m. Eq/L Compensated Respiratory Alkalosis Uncompensated Metabolic Acidosis Compensated Metabolic Acidosis Uncompensated Metabolic Alkalosis
Answer l l Answer is #4 Uncompensated Metabolic Alkalosis
Case Study 4 l A client is admitted to the hospital and is being prepared for a craniotomy (brain surgery). The client is very anxious and scared of the impending surgery. He begins to hyperventilate and becomes very dizzy. The client looses consciousness and the STAT ABGs reveal: l The results from the ABGs come back from the laboratory and show: p. H = 7. 57 Pa C 02 = 26 mm. Hg HC 03 = 24 m. Eq/L l l l 1. 2. 3. 4. Compensated Metabolic Acidosis Uncompensated Respiratory Alkalosis Uncompensated Respiratory Acidosis
Answer l l The answer is #3 Uncompensated Respiratory Alkalosis
Case Study 5 l A two-year-old is admitted to the hospital with a diagnosis of asthma and respiratory distress syndrome. The father of the infant reports to the nurse that he has observed slight tremors and behavioral changes in his child over the past three days. The attending physician orders routine ABGs following an assessment of the ABCs. The ABG results are: l p. H = 7. 36 Pa C 02 = 69 mm. Hg HC 03 = 36 m. Eq/L l l 1. 2. 3. 4. Compensated Respiratory Alkalosis Uncompensated Metabolic Acidosis Compensated Respiratory Acidosis Uncompensated Respiratory Alkalosis
Answer l l Answer is #3 Compensated Respiratory Acidosis
Case Study 6 l l 1. 2. 3. 4. A young woman, drinking beer at a party, falls and hits her head on the ground. A friend dials "911" because the young woman is unconscious, depressed ventilation (shallow and slow respirations), rapid heart rate, and is profusely bleeding from both ears. Which primary acid-base imbalance is this young woman at risk for if medical attention is not provided? metabolic acidosis metabolic alkalosis respiratory acidosis respiratory alkalosis
Answer l l Correct answer is #3 Respiratory Acidosis
Case Study 7 l l 1. 2. 3. 4. An 11 -year old boy is admitted to the hospital with vomiting, nausea and overall weakness. The nurse notes the laboratory results: potassium: 2. 9 m. Eq. Which primary acid-base imbalance is this boy at risk for if medical attention is not provided? metabolic acidosis metabolic alkalosis respiratory acidosis respiratory alkalosis
Answer l l Correct Answer is #2 Metabolic Alkalosis
Case Study 8 l l 1. 2. 3. 4. An elderly gentleman is seen in the emergency department at a community hospital. He admits to taking many tablets of aspirin (salicylates) over the last 24 -hour period because of a severe headache. He complains of an inability to urinate. His vital signs are: Temp = 98. 5; apical pulse = 92; respiration = 30 and deep. Which primary acid-base imbalance is the gentleman at risk for if medical attention is not provided? metabolic acidosis metabolic alkalosis respiratory acidosis respiratory alkalosis
Answer l l Correct Answer is #1 Metabolic Acidosis
Case Study 9 l l 1. 2. 3. 4. A young man is found at the scene of an automobile accident in a state of emotional distress. He tells the paramedics that he feels dizzy, tingling in his fingertips, and does not remember what happened to his car. Respiratory rate is rapid at 34/minute. Which primary acid-base disturbance is the young man at risk for if medical attention is not provided? metabolic acidosis metabolic alkalosis respiratory acidosis respiratory alkalosis
Answer l l Correct Answer is #4 Respiratory Alkalosis
ACID BASE PARAMETERS Respiratory Acidosis PH PCO 2 HCO 3 Respiratory Alkalosis PH PCO 2 HCO 3 Metabolic Acidosis PH PCO 2 HCO 3 Metabolic Alkalosis PH PCO 2 HCO 3
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