Mechanical Ventilation Cruise Control for the Lungs By
Mechanical Ventilation: Cruise Control for the Lungs By Diane Byrum, RN, CCNS, CCRN, MSN, FCCM, and Cherri Crabtree, RRT, RCP Nursing made Incredibly Easy! September/October 2009 2. 5 ANCC contact hours Online: www. nursingcenter. com © 2009 by Lippincott Williams & Wilkins. All world rights reserved.
Respiratory Failure ¡ Hypoxemic respiratory failure: Decreased Pa. O 2; most common cause for mechanical ventilation, including: • Pneumothorax • Atelectasis • Pulmonary edema • Pneumonia • Pulmonary fibrosis • early ARDS • smoke inhalation ¡ Hypercapnic respiratory failure: Decreased Pa. O 2 and normal or increased Pa. CO 2, including: • acute COPD exacerbation • head trauma • spinal cord injury
Other Conditions Requiring Mechanical Ventilation ¡ Bradypnea or apnea with respiratory arrest ¡ Respiratory muscle fatigue ¡ Acute lung injury ¡ Coma ¡ Tachypnea (respiratory rate of greater than 30 breaths/minute) ¡ Hypotension ¡ Neuromuscular disease ¡ Airway protection in patients with altered mental status or in clinical conditions in which the risk of pulmonary complications or respiratory failure is high ¡ Clinical deterioration for another condition unrelated to the lungs
Indications for Mechanical Ventilation ¡ Pa. O 2 less than 50 mm Hg with Fi. O 2 greater than 0. 60 ¡ Pa. O 2 greater than 50 mm Hg with p. H less than 7. 25 ¡ Vital capacity less than two times the tidal volume ¡ Negative inspiratory force less than 25 cm H 2 O ¡ Respiratory rate greater than 35 breaths/ minute
Endotracheal Intubation ¡ An ET tube is necessary ¡ Cuff pressure should be the lowest possible pressure to allow delivery of adequate tidal volume and prevent pulmonary aspiration; usually, at less than 25 mm Hg to prevent injury and at more than 15 mm Hg to prevent aspiration ¡ Monitor cuff pressure at least every 8 hours by attaching a pressure gauge monitoring device or using a minimal occlusion volume technique ¡ After the ET tube is in place, mechanical ventilation is initiated
Mechanics of Mechanical Ventilation ¡ The mechanical ventilator rate is defined as breaths delivered to the patient per minute; the initial rate is set to provide the needed ventilation to achieve a normal Pa. CO 2 value. ¡ Tidal volume is defined as the volume of gas exchanged during each ventilated breath, or the volume of air exhaled per minute; in mechanically ventilated patients, the tidal volume value depends on the patient’s lung condition and ideal body weight ¡ Minute ventilation is calculated by multiplying the ventilator rate by the tidal volume
Mechanics of Mechanical Ventilation ¡ PEEP is the pressure remaining in the lungs at end expiration; used to maintain the patency of the alveoli ¡ Fi. O 2 is the fraction of inspired oxygen (always expressed as a decimal, not a percentage) ¡ The P/F ratio is obtained by dividing the Pa. O 2 by the Fi. O 2; a normal P/F ratio is greater than 300, a value of less than 200 indicates refractory hypoxemia ¡ The initial ventilator rate will be adjusted based on the patient’s response, his ABG values, and the P/F ratio
Ventilator Modes 101 ¡ PSV mode delivers a set pressure that’s held during the entire inspiration while decreasing the patient’s work of breathing; patient must be spontaneously breathing ¡ AC mode delivers a set volume with each patienttriggered breath, as well as the set mechanical rate ¡ SIMV mode delivers a set number of breaths and tidal volume while allowing the patient to take spontaneous breaths with a patient-determined tidal volume and rate ¡ PC mode delivers a pressure-limited breath at a set rate; the tidal volume is determined by the set pressure limit ¡ Dual-control mode delivers a set tidal as a pressurelimited breath until the desired tidal volume is achieved
Initial Ventilator Settings ¡ Set the machine to deliver the tidal volume required. ¡ Adjust the machine to deliver the lowest concentration of oxygen to maintain normal Pa. O 2. ¡ Record PIP. ¡ Set the mode, rate, PEEP, and pressure support as ordered. ¡ Adjust sensitivity so that the patient can trigger the ventilator with a minimal effort.
Initial Ventilator Settings ¡ Record minute volume and obtain ABG values to measure Pa. CO 2, p. H, and Pa. O 2 after 20 minutes of continuous mechanical ventilation. ¡ Adjust the setting (Fi. O 2 and rate) according to the results of ABG analysis to provide normal values or those set by the healthcare provider. ¡ If the patient suddenly becomes confused or agitated or begins bucking the ventilator for some unexplained reason, assess for hypoxia and manually ventilate on 100% oxygen with a bag-valve mask.
Hazards of the Road ¡ Barotrauma—injury or damage to the lung tissue that can lead to entry of air into the pleural space (pneumothorax) or the tracking of air along the vascular bundle to the mediastinum (pneumomediastinum); high tidal volumes and peak plateau pressures are risk factors ¡ Volutrauma—damage to the lungs caused by too large a volume, leading to a syndrome of symptoms similar to ARDS ¡ Decreased cardiac output and BP— increased pressure in the lungs leads to increased pressure surrounding the heart and major vessels, which leads to decreasing blood return to the heart, decreased cardiac output, and eventually decreased BP
Hazards of the Road ¡ Oxygen toxicity—a combination of increased high levels of oxygen and prolonged use causing an inflammatory-like response in the lungs similar to ARDS; use the lowest Fi. O 2 setting that accomplishes the needed oxygenation to prevent ¡ Ventilator-associated pneumonia—as evidenced by new or changing pulmonary infiltrate on the chest Xray in conjunction with fever, leukocytosis, and a change in the color and amount of secretions ¡ Fluid retention, stress-related erosive syndrome, and increased ICP may also occur
Ventilator Alarms ¡ High PIP—increased airway pressure or decreased lung compliance, most often caused by secretions, coughing, or patient intolerance of the ventilator; always assess breath sounds for increased consolidation, wheezing, bronchospasm, or the possibility of a pneumothorax and check to see if the patient is biting on the tube, if the tubing is kinked, or if the tubing contains increased condensation ¡ Low minute ventilation—if the patient is on control mode, check for a disconnection or leak in the circuit; if he’s being weaned off the ventilator, assess for decreased respiratory effort ¡ Apnea—always check for patient effort and check for circuit disconnections that mimic apnea
A Team of Mechanics ¡ Nursing and respiratory therapy must collaborate when assessing for changes in the patient’s condition and administering ordered ventilator setting changes ¡ Most patients require some form of sedation; sedation holidays occur daily to assess the patient’s neurologic status and reorient him ¡ The patient’s readiness for weaning off the ventilator is assessed by conducting spontaneous breathing trials
Road Map to Success ¡ Elevate the head of the bed to greater than 30 degrees ¡ Provide mouth care every 4 hours, teeth brushing every 12 hours, and deep oropharyngeal suctioning every 12 hours ¡ Initiate stress ulcer prophylaxis using either histamine 2 -receptor blocking agents or proton-pump inhibitors ¡ Initiate deep vein thrombosis prophylaxis
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