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Premium member Presentation Transcript Ventilator Management: Ventilator Management Michael Schmitz, DO, MS Emergency Medicine/Internal Medicine October 10, 2007Objectives:: Objectives: To review differences in ventilator modes To review how to interpret ventilator settings and readings To discuss the protocol for assessing a ventilated patient who is in distress To review the pathophysiology of the obstructive lung diseases To discuss guidelines for ventilator settings for patients with obstructive lung diseaseSlide 3: 25 0.6 14 50 50 5 18 0.58 BUY “EASY TIGER” by RYAN ADAMS * * * * *Nomenclature: Nomenclature A/C 600/14/50%/+5Volume Cycled Ventilation: Volume Cycled Ventilation A/C Ventilation SIMVPressure Cycled Ventilation: Pressure Cycled Ventilation Pressure Support (PSV) Airway Pressure Release (APRV)Flow Rate / I:E Ratio: Flow Rate / I:E Ratio Flow Rate : a measure of the rate of delivery of oxygen through the system to the patient. (usually 60 liters per minute) I:E Ratio : a measure of total inspiratory time to expiratory time. (1:3) is ideal Inspiratory time = Tidal Volume / Inspiratory flow An increase in flow rate will shorten inspiratory time and decrease I:E Insufficient flow rates contribute to patient dyspnea Insufficient expiratory time increases mean airway pressure, the likelihood of barotrauma and auto-PEEP.Trigger Mode/Sensitivity: Trigger Mode/Sensitivity Trigger Mode - (A/C) Most common is “pressure triggering”; the patient must generate a sufficient NET negative airway pressure in order to receive a breath Sensitivity - the set negative pressure the patient must overcome to open the demand valve and trigger a breathFlow Pattern: Flow Pattern Constant (square) Decelerating (ramp) -possibly better in COPD SinusoidalPEAK VS. PLATEAU PRESSURES: PEAK VS. PLATEAU PRESSURES Peak Pressure: Pressure at the end of inspiration. Determined by inflation volume, airway resistance and the elastic recoil of the lungs and chest wall Plateau Pressure: Measured when airflow is stopped. It is directly proportional to the elasticity of the lungs and chest wallPEAK VS. PLATEAU PRESSURES: PEAK VS. PLATEAU PRESSURESSlide 12: * * * 25Positive End-Expiratory Pressure: Positive End-Expiratory Pressure PEEP : an elevation in alveolar pressure above atmospheric pressure at the end of exhalation Extrinsic PEEP (ePEEP): applied through a mechanical ventilator ACV without PEEP ACV with PEEPPositive End-Expiratory Pressure: Positive End-Expiratory Pressure improves gas exchange by opening small airways in the dependent lung zones and distributing inspired gas homogeneously. decreases expiratory flow limitation and dynamic hyperinflation. decreases oxygen consumption Physiologic: (3-5 cm H20) overcomes the decrease in functional residual capacity due to endotracheal intubation (glottis has been bypassed):Positive End-Expiratory Pressure: Positive End-Expiratory Pressure Supraphysiologic PEEP: (> 5 cm H20) Offsets auto-PEEP in patients with obstructive lung disease Improves oxygenation in patients with hypoxemic respiratory failure Improves oxygenation and cardiac performance in patients with cardiogenic pulmonary edema Caution in: focal lung disease, pulmonary embolism, hypotension, patients with increased ICP, hypovolemia, bronchopleural fistulaPositive End-Expiratory Pressure: Positive End-Expiratory PressureAuto-PEEP: Auto-PEEP Intrinsic PEEP ( i PEEP, aka occult, vent-associated) occurs because of incomplete ventilation: Initiating a new breath prior to complete exhalation causes air-trappingAuto-PEEP: Auto-PEEP Causes: high minute volume ventilation, expiratory flow limitation or increased expiratory resistance Hypoxemia, hypotension and barotrauma can occur as a resultAuto-PEEP: Auto-PEEPPEEP: PEEP Applying PEEP can decrease the magnitude of negative pressure that the patient must generate to trigger the ventilator, which reduces work done by the muscles of inspirationConsequences of MV: Consequences of MV Positive pressure ventilation preferentially inflates the more compliant, non-dependent upper lung zones Uneven gas distribution contributes to barotrauma and auto-PEEP, with a preference for damaging “normal” alveoli Occurs in ARDS, asthma and chronic interstitial lung diseaseConsequences of MV: Consequences of MV Barotrauma causes damage to adjacent alveoli via stretching and shearing forces. High peak airway pressures are directly correlated with barotraumaConsequences of MV: Consequences of MV Complications of alveolar rupture can be devastating: Pulmonary interstitial emphysema Pneumomediastinum SQ Emphysema Pneumothorax PneumoperitoneumVentilator Synchrony: Ventilator Synchrony Setting the ventilator to cycle with the patient’s respiratory rhythm Requires close patient monitoring Try to prevent ineffective triggering Adjust oxygen flow rate in proportion to tidal volume * may increase peak airway pressure Adequate sedation is critical Any increased sense of effort (fatigue vs. forced exhalation) on the part of the patient contributes to sensation of dyspneaCase Presentation: Case Presentation 65 year-old man BIBEMS c/o increasing dyspnea over 3 days associated with temperature of 100.3 and increase in thickened, green sputum. He has a history of emphysema, is on home oxygen and has been using his inhalers without relief.The Decision To Intubate: The Decision To Intubate Initiation of mechanical ventilation in COPD patients is associated with high patient mortality and poor potential for weaning Indications: (E.B.M. vs. clinical gestalt ) Patient failed conservative management Severe, persistent acidosis Continued arterial hypoxemia despite initial therapy Patient fatigue Altered mental status Additional major illness (pulmonary embolism, AMI)Slide 28: The usual vent settings are applied Some time passes………….Slide 29: 5 60 0.6 14 50% * * * * * 63 3:1 0.24 WARNING: LOW EXHALED VOLUME * *Respiratory Distress in MV : Respiratory Distress in MV Ventilator: Malfunction or Circuit Leak Ventilator: Inadequate ventilator settings: Inadequate Tidal volume, FiO2, Flow rate, Positive end expiratory pressure (PEEP) or over/undersensitivity Airway: (increased Ppeak-Pplat) ENDOTRACHEAL TUBE MIGRATION, patient biting tube, balloon cuff leak, deflation or rupture Bronchospasm, increased airway resistance imposed by heat and moisture exchanger, obstruction by secretions, blood or foreign objectRespiratory Distress in MV: Respiratory Distress in MV Lungs: (Ppeak-Pplat unchanged or decreased): pneumonia, atelectasis, pulmonary edema, aspiration of gastric contents, pneumothorax, pleural effusion, pulmonary embolus, ENDOTRACHEAL TUBE MIGRATION! Extrapulmonary: Abdominal distension, delerium, anxiety, pain, stroke, seizureRespiratory Distress in MV: Respiratory Distress in MVWhat to Do?: What to Do? ProtocolSlide 34: 56 *Slide 35: * 50 * Goals for COPD patients: Goals for COPD patients Adequate patient monitoring Optimize ventilator settings to minimize excessive work of breathing Assure Synchrony Detect auto-PEEP and prevent barotrauma Prevent further respiratory muscle atrophy Intubate using the widest diameter ET tube possible (R = 8nl / π r 4 )Obstructive Lung Diseases: Obstructive Lung Diseases Asthma Chronic bronchitis Emphysema Congenital bullous lung diseasePathophys COPD: Pathophys COPDPathophys Emphysema: Pathophys EmphysemaVent Guidelines: Vent Guidelines Emphasis on assisted modes of ventilation (patient initiated), institution preference for A/C vs. IMV with PSV (to overcome ET tube) SIMV: probably causes excess work, b/c of high resistance circuit but debatable; requires close patient monitoringVent Guidelines: Vent GuidelinesVENT Guidelines: VENT Guidelines Higher flow rates are highly beneficialVent Guidelines: Vent GuidelinesVent Guidelines: Vent Guidelines Tidal Volume: 5-7 ml/kg Set Rate: 4 less than spontaneous rate FiO2: adjust to PaO2 of at least 60 mmHg Triggering: -1 to -2 cm H2O Prevent Auto-PEEP with sufficient PEEP Flow rate: Increase to provide increased expiratory time (70-90 lpm) Continue inhaled medications: requires sufficient tidal volume and inspiratory timePathophys Asthma: Pathophys Asthma Airway narrowing caused by smooth muscle contraction, wall thickening and increased secretions combine to reduce air flow rates Primarily a disease of the AIRWAYS with decreased elastic recoil of the lungs during attack ABG for PaCO2 to identify respiratory failurePathophys Asthma: Pathophys AsthmaVent Settings Asthma: Vent Settings Asthma Respiratory rate 10 to 14 breaths/min (allows more time for exhalation) Tidal volume less than 8 mL/kg Minute ventilation less than 115 mL/kg Inspiratory flow of 80 to 100 L/min Extrinsic postive end-expiratory pressure less than 80 percent of the intrinsic PEEP Continue inhaled medications and steroidsVent Settings Asthma: Vent Settings AsthmaVent Settings Asthma: Vent Settings Asthma Intubate with largest diameter tube possible! (8.0 mm and up) First priority is to minimize auto-PEEP and keep plateau pressures low! Lower respiratory rate and tidal volume may be necessary causing PaCO2 to increase (permissive hypercapnia) Sedation, then paralysis to force synchrony HelioxOsteopathic Considerations: Osteopathic Considerations Findings reflect anatomical changes related to increased lung volumes and impaired ventilation Thoracic Vertebral Dysfunction Rib Dysfunction (stuck in exhalation) Diaphram Dysfunction (stuck down) Law of LaPlace T = Pr Lymphatic obstruction: lymphatic drainage impaired by positive pressureSummary: Summary The need to initiate mechanical ventilation in patients with obstructive lung disease in the emergency department is associated with a higher inpatient mortality Patients with obstructive lung disease require close monitoring of all physiologic parameters to prevent complications associated with positive pressure ventilation Assessing a distressed ventilator dependent patient requires an organized approach In general: low tidal volumes, higher flow rates and application of a conservative amount of PEEP are appropriate initial settings for patients with obstructive lung diseaseReferences: References “The ICU Book” Marino PL, 2 nd Edition “Respiratory Physiology” West JB, 5 th Edition “Pulmonary Pathophysiology” Grippi MA “Textbook of Medical Physiology” Guyton and Hall 9 th Edition “Chest Radiology Companion” Stern EJ, White CS Harrison’s Principles of Internal Medicine 16 th EditionReferences: References www.utdol.com : “principles of mechanical ventilation”, “alternate modes of mechanical ventilation”, “positive end expiratory pressure”, “pathophysiologic consequences of positive pressure ventilation”, “mechanical ventilation in acute respiratory failure complicating COPD”, “mechanical ventilation in adults w/ status asthmaticus” You do not have the permission to view this presentation. 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mechanical ventilator punjabi32 Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT lite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 326 Category: Education License: Some Rights Reserved Like it (2) Dislike it (0) Added: March 22, 2011 This Presentation is Public Favorites: 0 Presentation Description mechanical ventilator Comments Posting comment... Premium member Presentation Transcript Ventilator Management: Ventilator Management Michael Schmitz, DO, MS Emergency Medicine/Internal Medicine October 10, 2007Objectives:: Objectives: To review differences in ventilator modes To review how to interpret ventilator settings and readings To discuss the protocol for assessing a ventilated patient who is in distress To review the pathophysiology of the obstructive lung diseases To discuss guidelines for ventilator settings for patients with obstructive lung diseaseSlide 3: 25 0.6 14 50 50 5 18 0.58 BUY “EASY TIGER” by RYAN ADAMS * * * * *Nomenclature: Nomenclature A/C 600/14/50%/+5Volume Cycled Ventilation: Volume Cycled Ventilation A/C Ventilation SIMVPressure Cycled Ventilation: Pressure Cycled Ventilation Pressure Support (PSV) Airway Pressure Release (APRV)Flow Rate / I:E Ratio: Flow Rate / I:E Ratio Flow Rate : a measure of the rate of delivery of oxygen through the system to the patient. (usually 60 liters per minute) I:E Ratio : a measure of total inspiratory time to expiratory time. (1:3) is ideal Inspiratory time = Tidal Volume / Inspiratory flow An increase in flow rate will shorten inspiratory time and decrease I:E Insufficient flow rates contribute to patient dyspnea Insufficient expiratory time increases mean airway pressure, the likelihood of barotrauma and auto-PEEP.Trigger Mode/Sensitivity: Trigger Mode/Sensitivity Trigger Mode - (A/C) Most common is “pressure triggering”; the patient must generate a sufficient NET negative airway pressure in order to receive a breath Sensitivity - the set negative pressure the patient must overcome to open the demand valve and trigger a breathFlow Pattern: Flow Pattern Constant (square) Decelerating (ramp) -possibly better in COPD SinusoidalPEAK VS. PLATEAU PRESSURES: PEAK VS. PLATEAU PRESSURES Peak Pressure: Pressure at the end of inspiration. Determined by inflation volume, airway resistance and the elastic recoil of the lungs and chest wall Plateau Pressure: Measured when airflow is stopped. It is directly proportional to the elasticity of the lungs and chest wallPEAK VS. PLATEAU PRESSURES: PEAK VS. PLATEAU PRESSURESSlide 12: * * * 25Positive End-Expiratory Pressure: Positive End-Expiratory Pressure PEEP : an elevation in alveolar pressure above atmospheric pressure at the end of exhalation Extrinsic PEEP (ePEEP): applied through a mechanical ventilator ACV without PEEP ACV with PEEPPositive End-Expiratory Pressure: Positive End-Expiratory Pressure improves gas exchange by opening small airways in the dependent lung zones and distributing inspired gas homogeneously. decreases expiratory flow limitation and dynamic hyperinflation. decreases oxygen consumption Physiologic: (3-5 cm H20) overcomes the decrease in functional residual capacity due to endotracheal intubation (glottis has been bypassed):Positive End-Expiratory Pressure: Positive End-Expiratory Pressure Supraphysiologic PEEP: (> 5 cm H20) Offsets auto-PEEP in patients with obstructive lung disease Improves oxygenation in patients with hypoxemic respiratory failure Improves oxygenation and cardiac performance in patients with cardiogenic pulmonary edema Caution in: focal lung disease, pulmonary embolism, hypotension, patients with increased ICP, hypovolemia, bronchopleural fistulaPositive End-Expiratory Pressure: Positive End-Expiratory PressureAuto-PEEP: Auto-PEEP Intrinsic PEEP ( i PEEP, aka occult, vent-associated) occurs because of incomplete ventilation: Initiating a new breath prior to complete exhalation causes air-trappingAuto-PEEP: Auto-PEEP Causes: high minute volume ventilation, expiratory flow limitation or increased expiratory resistance Hypoxemia, hypotension and barotrauma can occur as a resultAuto-PEEP: Auto-PEEPPEEP: PEEP Applying PEEP can decrease the magnitude of negative pressure that the patient must generate to trigger the ventilator, which reduces work done by the muscles of inspirationConsequences of MV: Consequences of MV Positive pressure ventilation preferentially inflates the more compliant, non-dependent upper lung zones Uneven gas distribution contributes to barotrauma and auto-PEEP, with a preference for damaging “normal” alveoli Occurs in ARDS, asthma and chronic interstitial lung diseaseConsequences of MV: Consequences of MV Barotrauma causes damage to adjacent alveoli via stretching and shearing forces. High peak airway pressures are directly correlated with barotraumaConsequences of MV: Consequences of MV Complications of alveolar rupture can be devastating: Pulmonary interstitial emphysema Pneumomediastinum SQ Emphysema Pneumothorax PneumoperitoneumVentilator Synchrony: Ventilator Synchrony Setting the ventilator to cycle with the patient’s respiratory rhythm Requires close patient monitoring Try to prevent ineffective triggering Adjust oxygen flow rate in proportion to tidal volume * may increase peak airway pressure Adequate sedation is critical Any increased sense of effort (fatigue vs. forced exhalation) on the part of the patient contributes to sensation of dyspneaCase Presentation: Case Presentation 65 year-old man BIBEMS c/o increasing dyspnea over 3 days associated with temperature of 100.3 and increase in thickened, green sputum. He has a history of emphysema, is on home oxygen and has been using his inhalers without relief.The Decision To Intubate: The Decision To Intubate Initiation of mechanical ventilation in COPD patients is associated with high patient mortality and poor potential for weaning Indications: (E.B.M. vs. clinical gestalt ) Patient failed conservative management Severe, persistent acidosis Continued arterial hypoxemia despite initial therapy Patient fatigue Altered mental status Additional major illness (pulmonary embolism, AMI)Slide 28: The usual vent settings are applied Some time passes………….Slide 29: 5 60 0.6 14 50% * * * * * 63 3:1 0.24 WARNING: LOW EXHALED VOLUME * *Respiratory Distress in MV : Respiratory Distress in MV Ventilator: Malfunction or Circuit Leak Ventilator: Inadequate ventilator settings: Inadequate Tidal volume, FiO2, Flow rate, Positive end expiratory pressure (PEEP) or over/undersensitivity Airway: (increased Ppeak-Pplat) ENDOTRACHEAL TUBE MIGRATION, patient biting tube, balloon cuff leak, deflation or rupture Bronchospasm, increased airway resistance imposed by heat and moisture exchanger, obstruction by secretions, blood or foreign objectRespiratory Distress in MV: Respiratory Distress in MV Lungs: (Ppeak-Pplat unchanged or decreased): pneumonia, atelectasis, pulmonary edema, aspiration of gastric contents, pneumothorax, pleural effusion, pulmonary embolus, ENDOTRACHEAL TUBE MIGRATION! Extrapulmonary: Abdominal distension, delerium, anxiety, pain, stroke, seizureRespiratory Distress in MV: Respiratory Distress in MVWhat to Do?: What to Do? ProtocolSlide 34: 56 *Slide 35: * 50 * Goals for COPD patients: Goals for COPD patients Adequate patient monitoring Optimize ventilator settings to minimize excessive work of breathing Assure Synchrony Detect auto-PEEP and prevent barotrauma Prevent further respiratory muscle atrophy Intubate using the widest diameter ET tube possible (R = 8nl / π r 4 )Obstructive Lung Diseases: Obstructive Lung Diseases Asthma Chronic bronchitis Emphysema Congenital bullous lung diseasePathophys COPD: Pathophys COPDPathophys Emphysema: Pathophys EmphysemaVent Guidelines: Vent Guidelines Emphasis on assisted modes of ventilation (patient initiated), institution preference for A/C vs. IMV with PSV (to overcome ET tube) SIMV: probably causes excess work, b/c of high resistance circuit but debatable; requires close patient monitoringVent Guidelines: Vent GuidelinesVENT Guidelines: VENT Guidelines Higher flow rates are highly beneficialVent Guidelines: Vent GuidelinesVent Guidelines: Vent Guidelines Tidal Volume: 5-7 ml/kg Set Rate: 4 less than spontaneous rate FiO2: adjust to PaO2 of at least 60 mmHg Triggering: -1 to -2 cm H2O Prevent Auto-PEEP with sufficient PEEP Flow rate: Increase to provide increased expiratory time (70-90 lpm) Continue inhaled medications: requires sufficient tidal volume and inspiratory timePathophys Asthma: Pathophys Asthma Airway narrowing caused by smooth muscle contraction, wall thickening and increased secretions combine to reduce air flow rates Primarily a disease of the AIRWAYS with decreased elastic recoil of the lungs during attack ABG for PaCO2 to identify respiratory failurePathophys Asthma: Pathophys AsthmaVent Settings Asthma: Vent Settings Asthma Respiratory rate 10 to 14 breaths/min (allows more time for exhalation) Tidal volume less than 8 mL/kg Minute ventilation less than 115 mL/kg Inspiratory flow of 80 to 100 L/min Extrinsic postive end-expiratory pressure less than 80 percent of the intrinsic PEEP Continue inhaled medications and steroidsVent Settings Asthma: Vent Settings AsthmaVent Settings Asthma: Vent Settings Asthma Intubate with largest diameter tube possible! (8.0 mm and up) First priority is to minimize auto-PEEP and keep plateau pressures low! Lower respiratory rate and tidal volume may be necessary causing PaCO2 to increase (permissive hypercapnia) Sedation, then paralysis to force synchrony HelioxOsteopathic Considerations: Osteopathic Considerations Findings reflect anatomical changes related to increased lung volumes and impaired ventilation Thoracic Vertebral Dysfunction Rib Dysfunction (stuck in exhalation) Diaphram Dysfunction (stuck down) Law of LaPlace T = Pr Lymphatic obstruction: lymphatic drainage impaired by positive pressureSummary: Summary The need to initiate mechanical ventilation in patients with obstructive lung disease in the emergency department is associated with a higher inpatient mortality Patients with obstructive lung disease require close monitoring of all physiologic parameters to prevent complications associated with positive pressure ventilation Assessing a distressed ventilator dependent patient requires an organized approach In general: low tidal volumes, higher flow rates and application of a conservative amount of PEEP are appropriate initial settings for patients with obstructive lung diseaseReferences: References “The ICU Book” Marino PL, 2 nd Edition “Respiratory Physiology” West JB, 5 th Edition “Pulmonary Pathophysiology” Grippi MA “Textbook of Medical Physiology” Guyton and Hall 9 th Edition “Chest Radiology Companion” Stern EJ, White CS Harrison’s Principles of Internal Medicine 16 th EditionReferences: References www.utdol.com : “principles of mechanical ventilation”, “alternate modes of mechanical ventilation”, “positive end expiratory pressure”, “pathophysiologic consequences of positive pressure ventilation”, “mechanical ventilation in acute respiratory failure complicating COPD”, “mechanical ventilation in adults w/ status asthmaticus”