Expiratory Washout versus Optimization of Mechanical Ventilation during Permissive Hypercapnia in Patients with Severe Acute Respiratory Distress Syndrome

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Expiratory Washout versus Optimization of Mechanical Ventilation during Permissive Hypercapnia in Patients with Severe Acute Respiratory Distress Syndrome

JACK RICHECOEUR, QIN LU, SILVIA R. R. VIEIRA, LOUIS PUYBASSET, PIERRE KALFON, PIERRE CORIAT, and JEAN-JACQUES ROUBY

Réanimation Chirurgicale Pierre Viars, Department of Anesthesiology, La Pitié-Salpêtrière Hospital, University of Paris VI; the Medical ICU of Diaconesses Hospital, Paris; and the Medical ICU of Pontoise Hospital, Pontoise, France

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

The aim of this study was to compare three ventilatory techniques for reducing Pa_CO₂ in patients with severe acute respiratorydistress syndrome treated with permissive hypercapnia: (1) expiratorywashout alone at a flow of 15 L/min, (2) optimized mechanicalventilation defined as an increase in the respiratory frequencyto the maximal rate possible without development of intrinsicpositive end- expiratory pressure (PEEP) combined with a reductionof the instrumental dead space, and (3) the combination of bothmethods. Tidal volume was set according to the pressure-volumecurve in order to obtain an inspiratory plateau airway pressureequal to the upper inflection point minus 2 cm H₂O after settingthe PEEP at 2 cm H₂O above the lower inflection point and waskept constant throughout the study. The three modalities werecompared at the same inspiratory plateau airway pressure throughan adjustment of the extrinsic PEEP. During conventional mechanicalventilation using a respiratory frequency of 18 breaths/min, respiratoryacidosis (Pa_CO₂ = 84 ± 24 mm Hg and pH = 7.21 ± 0.12) was observed.Expiratory washout and optimized mechanical ventilation (respiratoryfrequency of 30 ± 4 breaths/min) had similar effects on CO₂ elimination( $Delta$ Pa_CO₂ = $-$ 28 ± 11% versus $-$ 27 ± 12%). A further decrease in Pa_CO₂was observed when both methods were combined ( $Delta$ Pa_CO₂ = $-$ 46 ± 7%).Extrinsic PEEP had to be reduced by 5.3 ± 2.1 cm H₂O during expiratorywashout and by 7.3 ± 1.3 cm H₂O during the combination of thetwo modes, whereas it remained unchanged during optimized mechanicalventilation alone. In conclusion, increasing respiratory rateand reducing instrumental dead space during conventional mechanicalventilation is as efficient as expiratory washout to reduce Pa_CO₂in patients with severe ARDS and permissive hypercapnia. Whenused in combination, both techniques have additive effects andresult in Pa_CO₂ levels close to normalvalues.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Acute respiratory distress syndrome (ARDS) is characterized by a low respiratory compliance and a reduced aerated lung volumethat result in compromised arterial oxygenation (1). Conventionalmechanical ventilation with high tidal volume, high peak airwaypressure, and high FI_O₂ can have detrimental effects in patientswith severe ARDS through ventilation- induced lung volutraumaand barotrauma (5). The concept of a "lung protective approach"in the ventilatory management of ARDS was first proposed by Hicklingand colleagues (9). These investigators observed in two nonrandomizedstudies performed in patients with ARDS a reduction in the actualmortality as compared with the predicted mortality when a pressure-and volume-limited ventilatory strategy was implemented (9,10). More recently, Amato and colleagues (11) evidenced animprovement in lung function and a decrease in mortality usinga similar ventilatory design combined with an active strategyof alveolar recruitment in a series of patients with severe ARDS.However, permissive hypercapnia that invariably results from sucha deliberate reduction of tidal volume has some potential drawbacksand may be poorly tolerated (14, 15). There is a consensusfor contraindicating its use in patients with brain edema, coronaryartery disease, severe metabolic acidosis, and severe hypoxemia(16). The addition of a continuous insufflation of gas in thetrachea to conventional mechanical ventilation allows a reductionin Pa_CO₂ (17). Insufflation of gas can be performed during theentire respiratory cycle (tracheal gas insufflation) or limitedto the expiratory phase (expiratory washout) (24). In the formermethod, gas insufflation raises airway pressure through an increasein tidal volume and expiratory flow limitation. In expiratorywashout (EWO) with volume-control ventilation, tidal volume remainsunchanged, but expiratory flow limitation also occurs, generatingintrinsic PEEP and reintroducing the risk of lung barotrauma (25).To maintain inspiratory plateau airway pressure constant, onepossibility is to reduce the level of extrinsic PEEP of an amountequivalent to EWO-induced intrinsic PEEP. During conventionalmechanical ventilation, another simple method for reducing Pa_CO₂is to increase the respiratory rate up to the limit of intrinsicPEEP and to decrease instrumental dead space by removing the respiratorytubing connecting the Y-piece and the proximal tip of the endotrachealtube. The goal of this prospective study was to compare the efficiencyof these techniques used alone or in combination for decreasingPa_CO₂ in patients with severe ARDS treated by a pressure- andvolume-limited ventilatorystrategy.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Patients

During a 12-mo period, six consecutive patients with ARDS diagnosed at the time of or after admission to the Surgical IntensiveCare Unit (Department of Anesthesiology) of La Pitié-SalpêtrièreHospital (Paris, France) were prospectively included in the study.Written informed consent was obtained from each patient's nextof kin. The study was approved by the Comité Consultatif de Protectiondes Personnes dans la Recherche Biomédicale of la Pitié-SalpêtrièreHospital. Inclusion criteria were: (1) bilateral infiltrates ona bedside chest radiograph and bilateral and extensive hyperdensitieson a high-resolution spiral thoracic computed tomographic (CT)scan; (2) pulmonary capillary wedge pressure less than 18 mm Hgand lack of left ventricular dysfunction as assessed by transesophagealechocardiography; (3) Pa_CO₂ $>=$ 50 mm Hg using the following ventilatorysettings with the patient sedated and paralyzed: volume-controlledmode with limited tidal volume to obtain a plateau airway pressurecorresponding to the upper inflection point of the pressure-volumecurve minus 2 cm H₂O, respiratory rate (RR) of 18 breaths/min,and PEEP equal to the lower infection point determined on thepressure-volume curve plus 2 cm H₂O. These inclusion criteriawere intended to select patients with severe ARDS at risk formechanical-ventilation-induced lung volutrauma in whom a pressure-and volume-limited ventilatory strategy was indicated. Exclusioncriteria were: (1) head injury, (2) severe hypertensive disease,(3) acute coronary insufficiency, and (4) severe metabolic acidosis.These exclusion criteria were intended to exclude patients inwhom permissive hypercapnia could have beenharmful.

All patients were orally intubated with a Hi-Lo Jet no. 8 Mallinckrodt tube (Mallinckrodt Inc., Argyle, NY), which incorporatestwo internal side ports, one ending at the distal tip of the endotrachealtube, which was used for airway pressure monitoring, and a moreproximal port ending 6 cm above, which was used for expiratorywashout administration. Patients were sedated and paralyzed witha continuous intravenous infusion of fentanyl 250 µg/h, flunitrazepam1 mg/h and vecuronium 4 mg/h and ventilated by a César ventilator(Taema, Antony, France) in a conventional volume-controlled mode.In all patients, hemodynamics were monitored using a fiberopticthermodilution pulmonary artery catheter (CCO/Sv_O₂/VIP TD catheter;Baxter Healthcare Corp., Irvine, CA) and a radial or femoral arterialcatheter.

High-resolution and Spiral Thoracic Computed Tomographic Scan

In order to assess the severity of ARDS, extension of lung consolidation was quantified by a thoracic computed tomographicscan. Each anesthetized and paralyzed patient was transportedto the Department of Radiology (Thoracic Division) and scanningwas performed from the apex to the diaphragm (Tomoscan SR 7000;Philips, Eindhoven, The Netherlands). All images were observedand photographed at a window width of 1,600 Hounsfield units (HU)and a level of $-$ 700 HU. A spiral CT consisting of contiguous axial10-mm-thick sections reconstructed from the volumetric data obtainedduring a 15-s apnea, the tracheal tube being disconnected fromthe ventilator, was acquired. A quantitative CT assessment ofparenchyma consolidation at zero end-expiratory pressure (ZEEP)was performed according to a previously described technique (26).Briefly, the radiologist manually traced the right and left lungoutlines with the roller ball on each spiral CT section from theapex to the diaphragm. Lung areas and mean lung density valueswere determined by using the region of interest function. Frequencyhistograms of the densities in HU were subsequently generatedfor each region of interest by using the analysis function. Thefrequency distribution of CT was computed for 50 compartments,from $-$ 1,000 HU to +100 HU, examining a 22-HU segment for eachcompartment. The frequency distribution of CT numbers of the entirelung was then calculated by adding the absolute values of eachcompartment. The lung volume of each compartment was calculatedby multiplying the following: number of lung pixels times squarepixel size times section thickness. Total lung volume was obtainedby adding the lung volume of each compartment. In order to differentiatethe lung zones with different degrees of ventilation, the entirelung was divided into three zones: lung zones between $-$ 1,000 and $-$ 500 HU were considered as normally aerated, those between $-$ 500and $-$ 100 HU as poorly aerated and those between $-$ 100 and +100HU as nonaerated (3).

Measurements

Systemic arterial pressure and pulmonary arterial pressure were measured simultaneously using the arterial cannula and thefiberoptic pulmonary artery catheter connected to two calibratedpressure transducers (91 DPT-308; Mallinckrodt) positioned atthe midaxillary line. Airway pressure was measured proximallyto the endotracheal tube connected to a third calibrated pressuretransducer (91 DPT-308; Mallinckrodt). At the end of each phase,signals were recorded at a high sample rate of 100 Hz on a dataacquisition and analysis system, including MP100 WS data acquisitionsystem (Biopac Systems Inc., Goleta, CA) and a Quadra 610 Macintoshcomputer (Apple Computer Inc., Cupertino, CA) connected to theanalog port of the hemodynamic monitor Merlin (Hewlett-Packard,Palo Alto, CA). Using the software AcqKnowledge included in theMP100 WS system, heart rate (HR), mean arterial pressure ( <OVL>Pa</OVL> ),mean pulmonary arterial pressure ( <OVL>Ppa</OVL> ), pulmonary capillary wedgepressure (Ppcw), right atrial pressure (PRA), and peak inspiratorypressure (Pmax) were measured. In addition, after activating thecorresponding knobs of the ventilator, inspiratory plateau airwaypressure (Pplat) was measured at the end of an inspiratory pauseof 3 s, and intrinsic PEEP was measured at the end of an expiratorypause of 5 s. Cardiac output was measured using the semicontinuousthermodilution technique (CCO/ Sv_O₂/VIP TD catheter). Systemicand pulmonary arterial blood samples were simultaneously withdrawnand arterial pH, Pa_O₂, Pv_O₂, and Pa_CO₂ were measured using anIL-BGE blood gas analyzer (Instrumentation Laboratories, Paris,France). Hemoglobin concentration, arterial and mixed venous oxygensaturations (Sa_O₂ and Sv_O₂) were measured using a calibrated OSM3hemoximeter (Radiometer Copenhagen, Neuilly-Plaisance, France).Standard formulas were used to calculate cardiac index (CI), pulmonaryvascular resistance index (PVRI), systemic vascular resistanceindex (SVRI), right ventricular stroke work index (RSWI), truepulmonary shunt ( $Q$ S/ $Q$ T), arteriovenous oxygen difference (C[a-v]O₂),oxygen delivery (DO₂), oxygen consumption ( $V$ O₂), and oxygen extractionratio (Ea_O₂).

Pressure-volume curves were obtained in ZEEP using an inspiratory occlusion technique derived from the one described by Levyand colleagues (27). Briefly, Pplat was measured at differentrandomized tidal volumes (100-ml increments) using the end-inspiratorypause hold functions of the César ventilator, while respiratoryrate remained constant at 18 breaths/min. Before administeringa given tidal volume, intrinsic PEEP was determined by activatingthe end-expiratory pause knob. The maximal plateau pressure authorizedwas 35 cm H₂O. After tracing the pressure-volume curve, staticrespiratory compliance (Crs) was calculated as the slope of thepressure-volume curve in its linear part, and lower and upperinflection points were visually determined. Quasi-static respiratorycompliance (Cqs) was determined by dividing the tidal volume ofthe patient by the corresponding end- inspiratory pressure minusintrinsicPEEP.

In each patient, expired CO₂ was measured using a nonaspirative calibrated 47210A infrared capnometer (Hewlett-Packard, Andover,MA) positioned between the proximal end of the endotracheal tubeand the Y-piece of the ventilator. Expiratory CO₂ curves wererecorded on the MP100 WS data acquisition system. After simultaneouswithdrawal of an arterial blood sample, the ratio of alveolardead space (VDA) to VT was calculated according to the followingequation:

V<SC>da</SC>/V<SC>t</SC>=1−P<SC>et</SC><SC>co</SC>2/Pa<SC>co</SC>2

where PET_CO₂ is end-tidal CO₂ measured at the plateau of the expired CO₂ curve. Because expiratory washout markedly interferedwith the expired CO₂ curve, VDA/VT was calculated only duringconventional and optimized mechanicalventilation.

In Patient 1, 10 ml of arterial blood were withdrawn at the end of each phase in order to determine epinephrine and norepinephrineplasma concentrations using a radioenzymatic assay based on theenzymatic methylation of epinephrine and norepinephrine by catecho-O-methyltransferase in the presence of triated S-adenosyl-L-methionine(radiolabeled SAMe³ H; Amersham). Normal values were 200 to 300 pg/ml for norepinephrine(intra-assay variability, 4.2%; interassay variability, 7.5%)and 25 to 55 pg/ml for epinephrine (intra-assay variability, 6%;interassay variability, 10%). In the five patients receiving exogenouscatecholamines for the treatment of their septic shock, accuratemeasurements were impossible because of the high concentrationsof catecholamines found in theplasma.

Expiratory Washout Administration

The ventilator used for the study was a César ventilator (Taema) equipped with a Fisher-Paykel humidifier positioned at theproximal tip of the inspiratory limb. The expiratory washout flowgenerator (Taema) was synchronized with the expiratory phase ofthe ventilator by means of a flow sensor connected to the inspiratorylimb of the ventilator giving the signal to interrupt the expiratorywashout flow when the inspiratory cycle started. An expiratorywashout flow of 15 L/min was delivered throughout the entire expirationvia the proximal channel of the endotracheal tube, itself connectedby a 3-mm internal diameter tube (Argyle; Sherwood Medical, Tullamore,Ireland) to the EWO module. Because the internal volume of thiscircuit was 15.5 ml and the driving pressure 1.3 bar, 4.7 ml ofgas were decompressed when EWO was interrupted and participatedto the nextinspiration.

Protocol

The study was performed over a 2-d period. On the first day, the protocol consisted of checking inclusion and exclusion criteria,obtaining initial hemodynamic and respiratory measurements innormocapnia, and performing the CT scan. At the end of the firstday, permissive hypercapnia was implemented according to the followingrationale: using conventional volume-controlled mechanical ventilation,a PEEP equal to the lower inflection point plus 2 cm H₂O was administeredand respiratory rate and inspiratory/expiratory (I/E) ratio wereset at 18 breaths/min and 33%. Then, VT was reduced in order toobtain a Pplat equal to the upper inflection point minus 2 cmH₂O or to 25 cm H₂O in the absence of an upper inflectionpoint.

The study itself was performed on the second day approximately 12 h after the implementation of permissive hypercapnia. Asshown in Figure 1, three ventilatory modes were tested in a randomizedorder: optimized mechanical ventilation using a respiratory frequencyof 30 ± 4 breaths/min, expiratory washout, and the combinationof the two. Each mode was separated from the preceding by a 1-hperiod of conventional mechanical ventilation with permissivehypercapnia (control). For each phase, a 1-h steady state wasobserved before measurements. Optimized mechanical ventilationconsisted of increasing the respiratory rate to the maximal ratepossible without development of intrinsic PEEP and removing the15-cm-long tubing connecting the proximal tip of the endotrachealtube and the Y-piece. When increasing respiratory frequency, theoccurrence of intrinsic PEEP was detected by the visual analysisof the expiratory flow displayed on the screen of the César ventilator.During expiratory washout and the combination of both modes, extrinsicPEEP was reduced in order to maintain the Pplat at its controlvalue. As a consequence, all ventilatory conditions were comparedat the same Pplat.

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Figure 1. Representation of the three different ventilatory modes. Each technique is represented at end-expiration in a separate quadrant with the ventilator César (V), inspiratory and expiratory limbs, the Y-piece, the tubing connecting the Y-piece to the endotracheal tube, the Mallinckrodt endotracheal tube and its two additional channels, and the tracheal carina. The dotted area represents respiratory tubing and upper airways with CO₂-laden gas. For each ventilatory technique, the corresponding flow is represented in the inferior part of the quadrant. Expiratory washout (EWO) is indicated by an additional flow superimposed on the expiratory flow. During optimized mechanical ventilation (OPTIMV), respiratory frequency is increased to the limit of intrinsic PEEP, and the tubing connecting the Y-piece to the endotracheal tube is removed.

Statistical Analysis

All data are presented as mean ± SD in the text and the tables and as mean ± SEM in the figures. Control conditions (conventionalmechanical ventilation) and the three experimental conditions(optimized mechanical ventilation, expiratory washout, and thecombination of these) were compared by a one-way analysis of variancefollowed by a Bonferroni multiple comparison test. Each conditionwas compared with its previous control by Student's paired t test.The interaction between optimized mechanical ventilation and expiratorywashout was tested by a two-way analysis of variance for two withinfactors. Level of significance was considered as 5%.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Patients

Individual characteristics of the patients are shown in Table 1. Five of the six patients received a continuous infusionof catecholamines for an associated septic shock. Survival ratewas 50%. According to the density histogram analysis, 41 ± 16%of the lung parenchyma was nonaerated, 41 ± 17% was poorly aerated,and only 18 ± 21% was normally aerated. The individual pressure-volumecurves of the patients are shown in Figure 2. Five patients hada Pplat above the upper inflection point determined on the individualpressure-volume curve when ventilated using conventional mechanicalventilation with PEEP. Individual hemodynamic and respiratoryparameters measured the first day of the study with a FI_O₂ of100% and using conventional mechanical ventilation with PEEP aresummarized in Table 2.

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TABLE 1

INITIAL CLINICAL CHARACTERISTICS OF THE SIX PATIENTS

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Figure 2. Individual pressure-volume curves of the total respiratory system obtained with the occlusion technique. All patients exhibited a lower inflection point, and all but one (Patient 4) exhibited an upper inflection point.

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TABLE 2

INITIAL INDIVIDUAL RESPIRATORY, METABOLIC, AND HEMODYNAMIC PARAMETERS DURING CONVENTIONAL MECHANICAL VENTILATION^*

Cardiorespiratory Effects of Reducing Tidal Volume during Conventional Mechanical Ventilation

Tidal volume was reduced by 43 ± 17% in order to reduce the Pplat to a mean value of 24 ± 3 cm H₂O, i.e., 2 cm H₂O below themean upper inflection point. The decrease in VT resulted in respiratoryacidosis: pH decreased from 7.39 ± 0.06 to 7.21 ± 0.11 and Pa_CO₂increased from 47 ± 6 to 84 ± 24 mm Hg (p < 0.05). Simultaneously, <OVL>Ppa</OVL> increased from 24 ± 5 to 29 ± 4 mm Hg (p < 0.05) and VDA/VTdecreased from 35 ± 10 to 25 ± 8%, corresponding to a decreasein alveolar dead space from 236 ± 63 to 100 ± 47 ml. All the otherparameters measured did not changesignificantly.

Cardiorespiratory Effects of the Three Ventilatory Modes

The hemodynamic and ventilatory parameters measured during the six phases of the study are shown in Table 3. The three controlphases (conventional mechanical ventilation) were similar forall the parameters tested. As shown in Figure 3, optimized mechanicalventilation and expiratory washout had similar effect on Pa_CO₂( $Delta$ Pa_CO₂ = $-$ 28 ± 11 versus $-$ 27 ± 12%), pH ( $Delta$ pH = +0.15 ± 0.04 versus+0.14 ± 0.03) and <OVL>Ppa</OVL> ( $Delta$ = $-$ 4 ± 3 versus $-$ 5 ± 4 mm Hg). Nosignificant changes in Pa_O₂ and $Q$ S/ $Q$ T were observed. ExtrinsicPEEP remained unchanged during optimized mechanical ventilation,but it had to be reduced by 44% during expiratory washout in orderto maintain the Pplat constant. This result suggests that expiratorywashout implemented at a respiratory rate of 18 breaths/min andat a flow of 15 L/min induced an intrinsic PEEP of 5 ± 2 cm H₂O.The addition of expiratory washout to optimized mechanical ventilationfurther decreased Pa_CO₂ by 18 ± 5%. As a consequence, the combinationof optimized mechanical ventilation and expiratory washout hadadditive effects and decreased Pa_CO₂ by 46 ± 7% as compared withconventional mechanical ventilation (Figure 3). Pa_CO₂ was below50 mm Hg in four of the six patients studied when optimized mechanicalventilation was combined with expiratory washout. In order tomaintain Pplat constant, extrinsic PEEP had to be further reducedto 4 ± 2 cm H₂O ( $-$ 61 ± 11%), and a slight but nonsignificant deteriorationin arterial oxygenation was observed.

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TABLE 3

RESPIRATORY, METABOLIC, AND HEMODYNAMIC PARAMETERS MEASURED DURING THE SIX PHASES OF THE STUDY

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Figure 3. Changes in Pa_CO₂, inspiratory plateau airway pressure (Pplat), PEEP, and Pa_O₂ (FI_O₂-1) induced by optimized mechanical ventilation (OPTIMV), expiratory washout (EWO), and the combination of OPTIMV and EWO in six patients with severe ARDS. Control values (control) were obtained during conventional mechanical ventilation using a respiratory frequency of 18 breaths/min and the presence of a 15-cm-long tubing connecting the Y-piece to the endotracheal tube.

The left panel of Figure 4 shows the profile of variations of PET_CO₂ when switching from expiratory washout, optimized mechanicalventilation, or the combination of both to conventional mechanicalventilation. A steady state in PET_CO₂ values was observed after30 min. The right panel of the figure shows the decrease in PET_CO₂when switching the ventilatory mode from conventional mechanicalventilation to optimized mechanical ventilation. A steady statewas also obtained after 30 min. In Patient 1, who did not receiveexogenous catecholamines, norepinephrine blood concentration decreasedfrom 776 to 198 pg/ml ( $-$ 75%), from 667 to 273 pg/ml ( $-$ 71%), andfrom 956 to 118 pg/ml ( $-$ 82%) with optimized mechanical ventilation,expiratory washout, and the combination of the two, respectively.Simultaneously, epinephrine blood concentration decreased from390 to 76 pg/ml ( $-$ 81%), from 363 to 103 pg/ml ( $-$ 77%), and from449 to 38 pg/ml ( $-$ 89%).

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Figure 4. (Left panel ) Profiles of increase in end-tidal CO₂ (PET_CO₂) when switching the ventilatory mode from expiratory washout, optimized mechanical ventilation, and the combination of both modes to conventional mechanical ventilation. For each patient, PET_CO₂ was measured each minute after the interruption of the mode, and the mean value of Pa_CO₂ corresponding to the three ventilatory modes was calculated. The mean value of the six patients is represented in the figure. (Right panel ) Profile of the decrease in PET_CO₂ when switching from conventional mechanical ventilation to optimized mechanical ventilation in the six patients of the study.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

This study, performed in patients with severe ARDS, demonstrates that Pa_CO₂ levels resulting from a pressure- and volume-limitedventilatory strategy can be maintained within safe limits whencombining expiratory washout with an optimization of mechanicalventilation. As a consequence many of the deleterious effectsresulting from severe hypercapnia such as pulmonary hypertension,tachycardia, high cardiac output, and catecholamine release canbe avoided in thesepatients.

Permissive Hypercapnia: Rational and Cardiopulmonary Effects

The patients included in the present study had severe ARDS as attested by the CT scan analysis and the alteration of theirrespiratory mechanics. Less than 20% of the lung parenchyma wasnormally aerated, whereas about 80% was either poorly aeratedor nonaerated on the CT scan performed at ZEEP. In five of thesix patients included, an upper inflection point was identifiedon the pressure-volume curve, with values ranging between 24 and33 cm H₂O, as previously reported (28). It is very likely thatmany of these patients were at risk of ventilator-induced lungbarotrauma since, at the end of each respiratory cycle, the Pplatwas above the upper inflection point when ventilatory parameterswere set to provide normocapnia. When VT was reduced to preventlung barotrauma, alveolar dead space decreased significantly byan amount of 136 ± 81 ml, strongly suggesting that mechanicalventilation set up for providing normocapnia was associated withan overdistension of some parts of the lung parenchyma. This resultis in accordance with the work by Kiiski and coworkers (29)who demonstrated that VDA/VT remains unchanged when VT is variedin patients with ARDS, suggesting that alveolar dead space increaseswith high tidal volumes and decreases with low tidal volumes.This dependency of dead space upon tidal volume seems specificto ARDS since it was not observed in healthy volunteers (30)or in patients with chronic obstructive pulmonary disease (31).

Permissive hypercapnia implemented over a 12-h period resulted in an increase in Ppa secondary to a nonsignificant increasein cardiac output and capillary wedge pressure. Neither Pa_O₂norshunt changed significantly. These hemodynamic and respiratorychanges were less pronounced than those occurring after an acutereduction in VT where a marked rise in pulmonary vascular resistanceand shunt fraction is classically observed (14). Differencesbetween the hemodynamic effects of acute and chronic permissivehypercapnia are likely related to differences in blood pH, thekidney allowing a time-dependant increase in bicarbonate plasmalevel with a concomitant increase in blood pH (12, 32). Itis also clear from the present study that a steady state in termsof Pa_CO₂ levels was obtained 30 min after acute changes in Pa_CO₂resulting from changing the ventilatorymode.

Cardiopulmonary Effects of Optimized Mechanical Ventilation and Expiratory Washout

Optimized mechanical ventilation improved alveolar ventilation by increasing minute ventilation ( $V$ E) through the increasein respiratory rate and by the reduction of instrumental deadspace. In intubated and mechanically ventilated patients, instrumentaldead space is composed of the endotracheal tube, the head exchangerfilter, and the tubing connecting the Y-piece to the endotrachealtube. In the present study, the head exchanger filter was replacedby a humidification chamber, and the tubing connecting the Y-pieceto the endotracheal tube was removed during optimized mechanicalventilation. This modification reduced the total instrumentaldead space by 40 ml, which decreased from 106 ml during conventionalmechanical ventilation to 66 ml during optimized mechanical ventilation.It has to be pointed out that the pneumotachograph and the capnometerhad a total internal volume of 27 ml and were also an integralpart of the instrumental dead space during conventional mechanicalventilation and the three methods tested. In clinical practice,these devices are not routinely used, and it can be speculatedthat their removal would have led to an additional reduction inPa_CO₂. In this category of patients with severe ARDS and reducedlung compliance, the respiratory frequency could be increasedto values around 30 breaths/min without generating intrinsic PEEPbecause of the stiffness of the respiratory system, allowing thelungs to completely deflate in an expiratory time less than 1.5s.

As previously reported, expiratory washout decreased Pa_CO₂ by removing the CO₂-laden gas occupying the endotracheal tube andthe tubing connecting the proximal tip of the endotracheal tubeand the Y-piece (25, 33, 34). As a consequence, the interfacebetween fresh inspiratory gas and CO₂-laden gas is shifted tothe distal part of the trachea, resulting in a reduction of deadspace to tidal volume ratio. There is also a superimposed jeteffect that produces projections beyond the site of administrationand removes further CO₂-laden gas from the distal portion of thetracheobronchial tree (18, 25, 35, 36). The efficacy ofexpiratory washout observed in our study was similar to the onedescribed by Nahum and colleagues in dogs (34) and by Kalfonand colleagues (25) in humans. Although the combination of optimizedmechanical ventilation and expiratory washout resulted in a spectacularreduction in Pa_CO₂ that even normalized in four patients, expiratorywashout was less efficient during optimized than during conventionalmechanical ventilation. It is highly likely that this differencewas related to the lower end-tidal fraction of CO₂ during optimizedmechanical ventilation. Nahum and colleagues (34) observed inhypercapnic dogs with oleic-acid-induced lung injury that expiratorywashout decreased Pa_CO₂ by 29 ± 5% when administered with a VTof 10 ml/kg, whereas Pa_CO₂ decreased by only 19 ± 3% when administeredwith a VT of 15 ml/kg (34). This result is explained by theparticular relationship between Pa_CO₂ and the dead space to tidalvolume ratio, which is curvilinear. Assuming a constant metabolicCO₂ production, at high level of Pa_CO₂ resulting from a smallVT and a low $V$ E, a given EWO-induced decrease in dead space,provides a significant drop in Pa_CO₂ because the system operateson the rectilinear part of the curve. If alveolar ventilationis increased by increasing respiratory rate, the Pa_CO₂ level decreasesand the same EWO-induced decrease in dead space will be associatedwith a less important decrease in Pa_CO₂ because the system operateson the flat part of the curve (34). In other words, the greaterthe end-tidal fraction of CO₂, the more efficient is the "washouteffect" on CO₂elimination.

Expiratory Washout-induced Intrinsic PEEP

A significant increase in airway pressure and in lung volumes is a well-known side effect of tracheal gas insufflation andcorrelates with the flow used (17, 18). When insufflationof gas is limited to the expiratory phase (expiratory washout),VT remains virtually unchanged during volume-control ventilation,but airway pressures can still increase through expiratory flowlimitation and intrinsic PEEP (25). Kalfon and colleagues (25),using an expiratory washout flow of 15 L/min, observed a 26% increasein Pplat related to expiratory flow limitation. In the presentstudy, extrinsic PEEP was adjusted in order to maintain Pplatconstant between the three ventilatory modes. This method allowsan indirect evaluation of expiratory washout-induced intrinsicPEEP. As expected, intrinsic PEEP was around 5 cm H₂O during expiratorywashout (25) and increased to 8 ± 2 cm H₂O when expiratory washoutwas combined with optimized mechanical ventilation. The differentbehavior of OPTIMV+EWO and EWO in terms of intrinsic PEEP mightbe explained by the following. The EWO module that was used inthe present study stops the expiratory gas flow 40 ms after thebeginning of inspiration, thereby increasing the VT by 10 ml.Five additional milliliters resulting from the decompression ofthe gas (see METHODS, EXPIRATORY WASHOUT ADMINISTRATION) are alsodelivered during early inspiration. Therefore, EWO increased VTby 3.5%. When respiratory frequency was low, this small increasein VT did not result in any detectable intrinsic PEEP becausethe respiratory system had enough time to empty. During OPTIMV,where respiratory rate was increased to the maximal rate possiblewithout development of intrinsic PEEP, by definition any increasein VT results in the occurrence of intrinsic PEEP. Therefore,it is not surprising that extrinsic PEEP had to be decreased significantlymore during OPTIMV+EWO than during OPTIMV alone. This result outlinesa critical issue of EWO: the flow generator should interrupt theexpiratory flow a few milliseconds before the beginning of theinspiratory phase in order to avoid any increase in VT. In addition,it can be expected that ending the expiratory flow before theinspiratory phase may prevent the occurrence of any intrinsicPEEP. Further studies are needed to verify this hypothesis. Becausemean airway pressure was carefully controlled throughout the study,no significant variation in Pa_O₂ was found between the three ventilatorymodes. This result contrasts with the 44% increase in Pa_O₂ describedby Kalfon and colleagues (25) when using expiratory washoutwithout controlling mean airway pressure. In this previous study,the increase in Pa_O₂ correlated with the increase in mean airwaypressure because of expiratory washout-induced intrinsic PEEP,suggesting that the improvement in arterial oxygenation resultedfrom an additional alveolar recruitment. This hypothesis is confirmedby the fact that arterial oxygenation did not improve in the presentstudy in which a careful control of airway pressure was obtained.As a consequence, these results suggest that expiratory washoutper se has no direct effect on alveolar recruitment when intrinsicPEEP does not induce an increase in mean airwaypressure.

In conclusion, during conventional mechanical ventilation, increasing respiratory frequency and reducing instrumental deadspace is as efficient as expiratory washout for reducing Pa_CO₂in patients with severe ARDS and treated by permissive hypercapnia.If expiratory washout-induced intrinsic PEEP is counterbalancedby a reduction of extrinsic PEEP in order to maintain the samelevel of mean airway pressure, Pplat and arterial oxygenationremain constant. When expiratory washout is combined with optimizedmechanical ventilation, a spectacular decrease in Pa_CO₂ is observed,resulting in a quasi-normal CO₂ elimination in a majority of patientsand questioning the concept of "permissivehypercapnia."

	Footnotes

Correspondence and requests for reprints should be addressed to Pr. J.-J. Rouby, Surgical Intensive Care Unit, Department of Anesthesiology, La Pitié-Salpêtrière Hospital, 47-83, boulevard de l'Hôpital, 75013 Paris, France. E-mail: jjrouby.pitie @invivo.edu

(Received in original form September 4, 1998 and in revised form December 24, 1998).

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