Effect of Ventilator Flow Rate on Respiratory Timing in Normal Humans

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Effect of Ventilator Flow Rate on Respiratory Timing in Normal Humans

RAFAEL FERNANDEZ, MANUEL MENDEZ, and MAGDY YOUNES

Section of Respiratory Diseases, Department of Medicine, University of Manitoba, Winnipeg, Manitoba, Canada

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Respiratory rate (RR) increases as a function of ventilator flow rate ( $V$ ). We wished to determine whether this is due toa decrease in neural inspiratory time (T In), neural expiratorytime (TEn), or both. To accomplish this, we ventilated 15 normalsubjects in the assist, volume cycled mode. Ventilator flow ratewas varied at random, at four breaths with each step, over theflow range from 0.8 ( $V$ min) to 2.5 ( $V$ max) L/s. V T was kept constant.The pressure developed by respiratory muscles (Pmus) was calculatedwith the equation of motion (Pmus = $V$ · R + V · E $-$ Paw, whereR = resistance, V = volume, E = elastance, and Paw = airway pressure).Electromyography of the diaphragm (Edi) was also done in fivesubjects. TIn and TEn were determined from the Pmus or Edi waveform.TIn decreased progressively as a function of $V$ , from 1.44 ± 0.34s at $V$ min to 0.62 ± 0.26 s at $V$ max (p < 0.00001). Changes inTEn were inconsistent and not significant. TIn/Ttot decreasedsignificantly (0.30 ± 0.06 at $V$ min to 0.18 ± 0.09 at $V$ max; p< 0.00001). We conclude that TI is highly sensitive to ventilatorflow, and that the RR response to $V$ is primarily related to thisT In response. Because an increase in $V$ progressively reducesT In/Ttot, and this variable is an important determinant of inspiratorymuscle energetics, we further conclude that inspiratory muscleenergy expenditure is quite sensitive to $V$ over the range from0.8 to 2.5 L/s.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

It is now well established that an increase in ventilator flow rate ( $V$ ), at a constant tidal volume (VT), results in an increasein respiratory rate (RR) and minute ventilation ( $V$ E), in bothnormal subjects (1) and in ventilator-dependent patients (5).We wished to determine whether this response is due to a reductionin neural TI (TIn), neural TE (TEn), or both. This informationis relevant to understanding of the mechanism(s) by which thetachypneic effect of ventilator inspiratory flow is mediated.The relation between ventilator flow and TIn is additionally importantfor the following two reasons:

TIn determines to a considerable extent the average pressure output of inspiratory muscles during mechanical ventilation (seeDISCUSSION). Defining the relation between ventilator flow andTIn would, accordingly, have implications relating to the workof breathing and inspiratory pressure output at different ventilatorsettings.
With conventional mechanical ventilation (volume cycled or pressure support ventilation [PSV]), the end of the ventilatorcycle is not linked to the patient's neural inspiratory phase.The relation between flow rate and TIn may be expected to haveimportant implications for synchrony between the patient's andthe ventilator's inspiratoryphases.

In the present study, we determined the response of neural TIn and TEn to systematic changes in inspiratory flow rate, ata constant VT, in normal subjects. We found that the increasein RR is produced principally by a reduction in TIn. The reductionin TIn with increasing flow was sufficiently pronounced that,above a certain flow, neural inspiration in many subjects terminatedalmost immediately after triggering. The results also indicatethat the reduction in TIn at higher flow rates is not the resultof more rapid attainment of the volume threshold for inspiratorytermination (the classical Hering-Breuer [H-B] reflex), but islargely a specific effect offlow.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

We studied 15 healthy nonsmoking volunteers (nine men and six women). Their average age was 28.0 yr (range: 20 to 39 yr),average height 170 cm (range: 152 to 188 cm), and average weight70 kg (range: 45 to 97 kg). None of the subjects was aware ofthe purpose of the study. Subjects were simply told that theywould be connected to a ventilator and that the ventilator settingswould be changed from time to time. They were asked to relax andnot to think about their breathing. They were instructed to signalor to disconnect themselves from the mouthpiece if they experiencedany distress. The project was approved by the human experimentationcommittee of our institution, and a consent form was signed byeachsubject.

The subjects were studied while awake and in the sitting position in a comfortable chair. They were connected via a mouthpieceto a locally constructed (Winnipeg, Manitoba, Canada) ventilator.A pneumotachograph was inserted between the Y-piece of the ventilatorand the mouthpiece to monitor $V$ and its integral, VT. Airwaypressure (Paw) was monitored through an appropriate port nearthe mouthpiece. In five subjects, electrical activity of the diaphragm(Edi) was monitored by inserting an esophageal catheter equippedwith two silver bands, 3 cm apart, near its tip. The catheterwas first advanced to 35 cm from the nares. The final positionof the catheter was associated with the most intense activityduring spontaneousbreathing.

The Winnipeg Ventilator is a flow triggered, piston-based ventilator. The flow level at which triggering occurred was setat the lowest level not associated with false triggering (usually0.1 to 0.2 L/s). The flow pattern of this ventilator, in the volume-cycledmode, is shown in Figure 1 at different peak flow settings. Peakflow is reached at approximately 0.2 s after triggering, and thendeclines gently until the set volume is reached. For the purposeof our study, the backup rate of the ventilator was set at zeroto insure that all breaths were triggered by the subject. End-expiratorypressure was zero (i.e., no positive end-expiratory pressure wasapplied).

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Figure 1. Tracings representing the typical flow pattern delivered by the ventilator at different peak flow settings.

Signals related to flow, volume, and Paw were stored at 50 Hz in a personal computer by means of commercial software (Windaq;DATAQ Instruments Inc., Akron, OH). When Edi was monitored, theelectrical signal was bandpass filtered (30 to 1,000 Hz) and storedat 500 Hz (two subjects) or 1,000 Hz (three subjects). The signalwas processed post hoc by computer as follows: (1) the signalwas rectified; (2) a custom-written computer algorithm scannedthe signal, identifying QRS complexes; (3) the raw electricalactivity was deleted over the period corresponding to the QRScomplex (usually 100 ms), and was replaced by artificial valuesrepresenting a linear interpolation between average activitiesimmediately before and immediately after the QRS complex (Figure2, channel 5 [Processed Edi]); and (4) a moving average (100 ms)of the rectified signal was obtained (Figure 2, channel 6 [EdiMA]).

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Figure 2. Tracings of airway pressure (Paw); flow; volume; raw EMG of the diaphragm (raw Edi); Edi after removal of the QRS complex and rectification (processed Edi), and after averaging (Edi MA); and calculated Pmus. (A) Onset of neural inspiration (point at which Pmus begins rising and there is a change in trajectory of Paw and flow). (B) Ventilator triggering (point at which Paw begins rising). C₁ = end of TIn defined from Pmus (point at which Pmus begins steady decline to baseline). C₂ = end of TIn defined from Edi (point at which EdiMA begins a steady decline to baseline). (D) End of ventilator cycle (point at which Paw and flow begin a rapid decline). TIn is interval A-C. Triggering time (T_tr) is interval A-B. $Delta$ Tend is interval C-D. Vth is volume at the end of neural inspiration (point C₁ or C₂).

Protocol. Upon switching to the volume-cycled mode, we set the ventilator VT and peak flow settings to the lowest levels deemedcomfortable by the subject. This was achieved by trying differentsettings while obtaining feedback from the subject. After thesebaseline settings were established ( $V$ = 0.81 ± 0.19 L/s, VT =1.10 ± 0.4 L), ventilator flow was changed to different levels,with each level maintained for four breaths. From six to eightflow steps were tested. These spanned the range between baselineflow and a maximum peak flow setting of 2.5 L/s (Figure 1). VTwas kept constant at its baseline value. Each flow setting wastested from four to eight times, which, after deletion of breathshaving artifacts (swallowing, movement, etc.), resulted in 12to 32 breaths per flow setting per subject. To evaluate the validityof the four breath tests, transitions from one flow rate to ahigher flow rate were maintained for 1 to 2 min in 10 subjects.Three such longer transitions were made in eachsubject.

Throughout the foregoing protocol, silence was maintained in the laboratory and the subject was deprived of any clues thatwould alert him/her to an impending change in ventilator settings.The order of application of the different flow rates wasrandomized.

After completion of the flow-adjustment protocol, the ventilator backup rate and VT were gradually increased until ventilationwas controlled without evidence of respiratory effort. This wasdetermined from the absence of triggering efforts; from reproduciblePaw waveforms during inspiration without evidence of scalloping;and from a smooth, exponential decline in flow during expiration(6). At this point the subject was told that exhalation wouldbe blocked for a brief period, and was asked to relax during thesemaneuvers. Several such end-inspiratory occlusions were applied.Maneuvers resulting in an acceptably stable plateau pressure (Pplat)were used to calculate elastance (E) and resistance (R) accordingto standard formulae (E = Pplat/VT; R = [Ppeak $-$ Pplat] / $V$ ).

Analysis. The pressure developed by respiratory muscles (Pmus) was continuously computed from the stored Paw, $V$ , and V dataaccording to the equation of motion (7), modified for subjectson a ventilator (8):

Pmus=V⋅E+<A><AC>V</AC><AC>˙</AC></A>⋅R−Paw (1)

We assumed that volume at the beginning of inspiration was passive FRC. We ignored inertia. Inertial pressure losses are usuallyvery small during spontaneous breathing, since the accelerationand deceleration of flow during natural breathing are relativelyvery small (7). In the current study, particularly at the highestflow settings, the sudden reduction in flow at the end of theventilator cycle was associated with deceleration values thatwere sufficiently high (up to 100 L/s²) to be associated with measurable inertial pressures. Becausewe did not include inertial forces in the equation of motion,a brief artifact occurred in the calculated Pmus in some subjectsat the time of switching off of the ventilator. We elected notto include inertial losses in the computation of Pmus, since accuratevalues of inertia are not available for the conditions of ourexperiment, and because the artifactual nature of the pressurespike could be easily determined (its occurrence was limited tothe phase of sharp decline in $V$ , it had a very brief duration,and its peak occurred at the point of fastestdeceleration).

The onset of neural inspiration was defined as the point at which Pmus began rising from baseline (Point A, Figure 2). Thispoint was invariably associated with a change in trajectory ofPaw and flow in an inspiratory direction (in fact, it is thischange in trajectory of Paw and flow that is responsible for theincrease in calculated Pmus). The end of neural inspiration wasdefined as the point at which Pmus began a monotonic decline towardbaseline (Point C₁, Figure 2). TIn was taken as the interval betweenthese two points. We also determined the point at which the triggeringof the ventilator occurred (the point at which Paw changed directionfrom falling to rising, and at which flow rate increased abruptly[Point B, Figure 2]). The time to triggering (Ttr) was the differencebetween the time of onset of inspiration and that of triggering(Points A and B, respectively, Figure 2). The end of the ventilatorcycle was identified as the point at which Paw and flow begandeclining sharply (Point D, Figure 2). The interval between theend of the ventilator cycle and the end of neural inspiration( $Delta$ Tend) was calculated (Interval D-C₁, Figure 2). Total cycleduration (TTOT) was taken as the interval between the onset ofinspiration and the onset of the next inspiration (Interval A-A,Figure 2). Neural expiratory duration was calculated from Ttot $-$ TIn. The volume at which neural inspiration terminated (Vth)was noted (volume at point C₁, Vth, Figure 2).

In the five subjects in whom Edi was monitored, the same variables were measured from both the Pmus and averaged Edi signals.Scoring from the two signals was done independently (Edi was offthe screen when scoring from Pmus was done, and vice versa). Whenscoring was done from Edi, the onset of inspiration was definedfrom the point of inspiratory inflection in Paw and flow. Oneor both of these signals was inspected at high gain to facilitatethe detection of this event. We chose to identify inspiratoryonset from Paw and $V$ (as opposed to using Edi) for two reasons.First, baseline artifacts in the moving average of Edi often madeit difficult to precisely identify the point at which Edi begandeviating from baseline. Second, we wanted to use the same pointas the onset of inspiration for both Pmus and Edi (but withoutlooking at Pmus), so that comparisons between TIn as measuredwith the two signals primarily reflected differences in the definitionof the end of TIn. This is the point at which there is uncertaintyabout the validity of Pmus. The end of neural inspiration wasdefined as the point at which averaged Edi began a monotonic descentto baseline (Point C₂, Figure 2). Other variables were determinedas with the Pmusanalysis.

Results for each variable were segregated according to peak flow rate. Average values were obtained for each subject at eachflow setting. The effect of flow on the variables of interestwas determined for the 15 subjects through analysis of variancefor repeated measures (ANOVA). A value of p < 0.05 was consideredsignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Figures 3A to 3E shows the relation between TIn measured from Pmus (TI Pmus) and from Edi (TIEMG) in the five subjects inwhom Edi was monitored. Each point in the figure represents asingle breath. There was good agreement between the two measurementsover the entire flow range in all subjects (r = 0.78 to 0.99,Figures 3A to 3E). The variability appeared to be mostly random,in that data points were scattered on both sides of the line ofidentity. To assess whether there were any systematic differencesbetween the two measurements at the different flow rates, we averagedthe values of TIPmus and TIEMG over the different flow rangesused in individual subjects. The results are shown in Figure 3F.As can be seen, although some differences remained in some casesafter averaging, these were small. More importantly, these differencesdid not affect the estimated change in TIn as a result of changesin flow rate. Thus, the average (± SD) change in TIn between thehighest and lowest flow rates in the five subjects was 0.612 ±0.18 s when measured from Pmus, and 0.618 ± 0.24 s when measuredfrom Edi. There was no significant difference between these means,whereas there was a significant correlation between the two measurements(r = 0.87).

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Figure 3. Relation between neural inspiratory duration determined from EMG of diaphragm (TIEMG) and from calculated Pmus in five subjects in whom both measurements were made. (A-E ) Relation in individual subjects. Each point represents a single breath. Data are from observations at all flow rates studied. (F ) Same results after averaging data points at different flow rates. Each symbol represents a different subject. In each subject, points with lower TI are associated with higher flow rates, and vice versa.

Figure 4 shows representative examples of the response of TIn at different flow settings in one subject. Note the progressivereduction in TIn and Ttot as flow increased. Note also that atthe highest flow settings, TIn terminated very shortly (0.28 s)after triggering.

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Figure 4. Representative examples of responses observed at five different peak flow settings in one subject. Paw = airway pressure, Edi = diaphragmatic EMG, EdiMA = moving average of Edi after rectification and removal of QRS complex, Pmus = calculated pressure output of inspiratory muscles. Note the progressive reduction in TIn and Ttot as flow increases.

The individual changes in TIn and TEn are shown in Figure 5. With the exception of one subject, in whom the response laggedsomewhat, TIn decreased progressively in all subjects as flowincreased, beginning with the first step increase (Figure 5, left).The average response of TIn for the group is shown in Figure 6A.Highly significant reductions in TIn were observed beginning withthe second step change in flow (p < 0.0001 or lower, ANOVA). TIndecreased to less than half its baseline value (0.62 ± 0.26 sversus 1.44 ± 0.34 s) between baseline flow ( $V$ = 0.82 ± 0.2 L/s)and the highest flow rate ( $V$ = 2.58 ± 0.2 L/s). The responseappeared to level off at last step increase in flow. This, however,was largely due to the fact that in seven subjects, TIn had reachedthe minimum possible value that can be achieved in these experiments,this minimum value being dictated by the triggering delay (0.28± 0.05 s) and a finite response latency (Figure 5, left).

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Figure 5. Individual responses of neural inspiratory duration (left) and neural expiratory duration to changes in ventilator flow rate. Each line represents one subject. Solid lines are from five subjects in whom timing was assessed from Edi. Interrupted lines are from subjects in whom timing was assessed from Pmus. Note that individual responses of TIn are fairly uniform among subjects, whereas the responses of TEn are inconsistent.

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Figure 6. Average responses of various output variables at different flow rates. TIn = neural inspiratory duration, TEn = neural expiratory duration, Ttot = breath duration, TIn/Ttot = inspiratory duty cycle, $Delta$ Tend = time interval between the end of ventilator inflation phase and the end of neural inspiration. *Significant difference from value at lowest flow (ANOVA). Bars represent SEM.

The individual responses of TEn were inconsistent both within and among subjects (Figure 5, right). The average response showeda tendency (p = NS) for TEn to decrease over the first few flowsteps (Figure 6B). Changes in Ttot (Figure 6C) reflected the combinedeffect of changes in TIn and TEn, showing a relatively steep decreaseover the first three steps (both TIn and TEn decreasing), witha tendency for the response to level off in the high flow rangeas a result of reciprocal changes in TIn and TEn. TIn/Ttot decreasedsignificantly as flow increased (Figure 6D). At baseline flowthe ventilator cycle extended beyond TIn by an average (± SD)of 0.43 ± 0.28 s (Figure 6E). This difference ( $Delta$ Tend) showed abiphasic response to increasing flow. Initially, TIn decreasedless than ventilator TI, and the difference ( $Delta$ Tend) narrowed toa minimum of 0.21 ± 0.19 (p < 0.003 by comparison with baseline).At still higher flows, TIn decreased more than TIM, and $Delta$ Tendincreased again. There was no change in triggering delay as flowincreased (Ttr = 0.32 ± 0.06 s at baseline versus 0.28 ± 0.05s at the highestflow).

Figure 7 shows the average breath-by-breath change in TIn after flow transitions that were maintained for at least 12 breaths.The change in TIn was nearly complete within the first breathafter transition, and there were no systematic time-dependentchanges thereafter (ANOVA).

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Figure 7. Average time course of flow and neural inspiratory duration during flow transitions that lasted at least 12 breaths. The results are the average of data from 10 subjects in whom this was done. (B) Average value immediately before flow transition. *Significant differences from baseline value (ANOVA). There were no significant differences between any of the breaths following transition. Bars represent SEM.

Figure 8 shows the average relation between TIn and the volume delivered by the ventilator at the time of switching (Vth).As TIn decreased, Vth initially tended to increase, but subsequentlydeclined progressively. Vth at the highest two flow rates (shortestTIn) was significantly lower than Vth at the third flow level(0.58 L and 0.59 L, respectively, versus 0.86 L; p < 0.01).

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Figure 8. Average relation between neural inspiratory duration and volume at point of termination of neural inspiration. Dotted line is the anticipated response based on the classical inspiratory terminating Herring-Breuer reflex. This line has no quantitative significance, but is placed here simply to show that according to this classical reflex, the volume threshold at inspiratory termination should be higher with shorter inspiratory times. Note that the response in the current experiments is qualitatively different from the expected response, in that the volume at switching tends to decrease as TIn decreases, indicating that the earlier switching is not related to earlier attainment of a volume threshold. Bars represent SEM (some bars were omitted for clarity). ⁺Significantly higher than values at shortest TIn (p < 0.005).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The main findings in the present study were that TIn is strongly influenced by ventilator flow rate, and that this responseis not due to earlier attainment of the volume threshold for inspiratorytermination (the classic H-B reflex). Rather, the response appearsto be specifically related toflow.

Technical Considerations

In the majority of subjects (10 of 15), neural timing was inferred from a calculated mechanical output (Pmus). This approachmay be criticized on the grounds that accurate Pmus determinationsdepend on accurate estimates of passive respiratory mechanics,which are difficult to obtain in awake subjects. Our faith inthis approach is based on two considerations. First, althoughit has long been recognized that relaxation of respiratory muscles,on command, is difficult to achieve in awake, untrained subjects,it has recently been shown that loss of inspiratory muscle activityis readily attained in normal awake subjects when they are connectedwith a constant-volume ventilator and the mandatory ventilationrate is increased sufficiently (6). Furthermore, the criteriafor relaxation under these conditions have been well established(6, 9). What was required of our subjects was simply notto voluntarily activate their expiratory muscles in response tothe inspiratory hold maneuver. This is a much easier task thanto voluntarily relax inspiratory muscles at different volumes.Furthermore, voluntary recruitment of expiratory muscles afterthe onset of end-expiratory occlusion would be easily recognized.Because the subjects did not anticipate the occlusions and becausethere is a minimum delay of 0.2 s for voluntary recruitment ofrespiratory muscles (11, 12), recruitment of expiratory muscleswould appear as a secondary rise in Paw after an initial fall.Second, according to the equation of motion (Equation 1), errorsin estimating elastance and resistance, in the face of a nearconstant flow, should result, respectively, in errors in estimatingthe rate of rise of Pmus or in a constant shift in the whole waveformwithout affecting the point in time at which Pmus changes directionfrom rising to falling. It was this inflection point in whichwe were interested. Although in theory the time of occurrenceof the inflection point can be artifactually altered in the presenceof nonlinearities in the passive pressure-flow and pressure-volumerelations, we felt that these conditions would not apply in ournormal, mouth-breathing subjects over the VT and flow ranges used(7, 10).

The validity of using calculated Pmus to estimate the end of TIn was determined independently from Edi and Pmus over a widerange of flows (Figure 3). Much of the difference between thetwo measurements appeared random. In retrospectively reviewingthe reasons for the difference, we found that it was mostly dueto uncertainty about when diaphragmatic electromyographic activitybegan declining. As can be seen from Figures 2 and 4, the Edisignal remained jagged despite elimination of the QRS complexand averaging at 100 ms. More severe filtering would have furthersmoothed the signal, but would also have altered the point ofinflection. With the processing used in the study, there wereoften two peaks, and the decision about which constituted theend of TIn was subjective (e.g., see Figures 4B and 4C). We usuallyselected the last peak, but this could easily have been noiseon the descending limb. Alternatively, a large spike occurringnear the end of the rising phase might have led to false earlyidentification of the end of TIn. After averaging to eliminatethis random error, there were minor systematic differences (Figure3F). In most of the cases in which differences existed, TIP_musslightly but systematically exceeded TIEMG. This may have beenrelated to pressure output essentially being a damped expressionof muscle activation due to muscle mechanical delays. Furthermore,Pmus reflects the output of all muscles and not only the diaphragm,and it is possible that termination of activity in other musclesmay have lagged somewhat. These systematic differences, however,were quite small (Figure 3F), and did not affect the magnitudeof estimated change in TIn as a function of flow. In further supportof the validity of Pmus in assessing TIn is that the changes observedin TIn with flow in five subjects in whom Edi was conducted didnot differ from those observed in the other 10 subjects, in whomonly Pmus was used (Figure 5, compare solid lines with brokenlines). One exception, however, should be noted. In one subject,the data points were scattered around the line of identity atall flow rates except the highest flow (shortest TIn), where TIP_musappeared to systematically underestimate TIEMG (Figure 3C). Thiswas also apparent in the averaged data ("+" symbols, Figure 3F).An example of a breath in which TIP_mus underestimated TIE_di isshown in Figure 9A; peak Pmus preceded peak Edi by 0.2 s. We believethat this was due to a combination of underestimation of resistance,very high peak flow, and termination of neural inspiration soonafter peak flow was reached. The underestimation of resistancewould cause a stepwise reduction of estimated Pmus at triggering,which, in the face of a large flow, as in this case (~ 3.0 L/s)could cause a sharp, steep decline in estimated Pmus. Ordinarily,if inspiratory activity continued increasing well after peak flowwas reached, the error would reach a maximum at peak flow, andPmus would rise again to a new peak (e.g., Figure 9B). The artifactualnature of the first peak would be apparent. When inspiratory activityterminates soon after peak flow is reached, the early artifactualreduction in Pmus merges with the later reduction, owing to truetermination of inspiration, and the error is not identified. Thisartifact was present in only one of the five subjects in whomEdi was measured, and only at the highest peak flow rate (3 L/s);however, it may have played a role in producing the very shortTIP_mus points at the highest flow in some of the other 10 subjects.Nevertheless, it must be reiterated that occurrence of this artifactwould require true TIn to terminate very early, soon after peakflow was reached. In other words, it can only make a short TInappear somewhat shorter, but cannot cause TIn to appear shortwhen it is not.

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Figure 9. Example of artifactual early termination of TIn Pmus in one subject. (A) Pmus begins declining before Edi. The decline coincides with ventilator triggering and is progressive beyond the point of peak flow. (B) Another breath soon after (A) in the same subject. TIn (by EMG) is somewhat longer. Pdi also begins declining at triggering. However, because TIn extends well beyond peak flow, Pmus begins rising again beyond peak flow, reaching a new peak. The artifactual nature of the first peak becomes apparent. See text for additional comments. The sharp positive spike in Pmus at the time of off-cycling of ventilator is related to inertial forces that are not taken into account in the Pmus calculation (see data analysis). This was particularly prominent in this subject (cf. subjects illustrated in Figures 2 and 4).

In summary, we believe that the changes in TIn, and hence in TEn, observed with Pmus adequately reflected the correspondingchanges in neural timing in the entire group of oursubjects.

Response of Neural Inspiratory Duration

The response of TIn to increasing flow rate was remarkably strong. Increasing flow rate resulted in an average reduction inTIn of 0.82 ± 0.30 s over the flow range used. When allowancewas made for trigger delays (0.28 ± 0.05 s), TIn lasted an averageof 0.34 ± 0.27 s beyond triggering at the highest flow rate. Theresponse was graded and was fairly uniform among subjects (Figure5, left).

The first issue to be discussed with respect to the mechanism of the TIn response is whether it is a deliberate behavioralresponse or is automatic (reflexive). Because the subjects werealert, and ventilator TI changed inversely with flow rate (constantVT), it may be argued that subjects deliberately reduced TIn asflow increased, in order to avoid continued effort after the endof the ventilator cycle. There are several arguments against thispossibility. First, the response of TIn mirrors the response ofTtot and is in fact the main reason why Ttot decreases with increasingflow (Figure 6). The response of Ttot to ventilator flow has beenshown to persist during sleep (2, 4), making it very likelythat the response of TIn also persists during sleep, and is thereforenot deliberate. Second, the considerable uniformity of responseamong subjects, and during several applications of the same flowat different times in the same subject, argues against volitionalresponses, which would be expected to show considerable interindividualand intraindividual (due to different levels of vigilance) variability.Third, changes in flow were applied in random order. At leastfor the first breath after a flow transition, there was no wayfor the subject to anticipate what ventilator TI would be. Therewas no significant difference between the response in the firstbreath and the response in subsequent breaths (Figure 7).

A host of reflexes are responsive to mechanical variables and are capable of altering respiratory timing. These originatefrom receptors in the upper airway (13), in the chest wall (14-18), and in the lungs and bronchi (17). It is unlikely thatthe TIn response observed in our study was mediated primarilyby upper-airway receptors. This assessment is based on our findingthat the Ttot response was the result of shortening of TIn, coupledwith recent observations that the Ttot response to increasingflow, at constant VT, is not altered by upper-airway anesthesia(3), and is intact in intubated patients in whom the upperairway is bypassed (5).

The TIn response is also unlikely to be mediated by chest wall receptors. This is because reflexes from the chest wall thathave effects on TI are quite weak and tend to shorten TIn whenthe mechanical load is increased (21, 22), whereas what weobserved was a reduction in TIn as the mechanical load was decreasedthrough an increase in ventilatorflow.

The reflex that would most obviously account for the current findings is the vagally mediated, inspiratory terminating (H-B)reflex (23, 24). In anesthetized animals, changes in VT, producedby changes in ventilator gain (23) or in mechanical load (24),result in reciprocal changes in TIn, as schematically representedby the dashed line in Figure 8. This reflexive activity is believedto be mediated by the slowly adapting vagal stretch receptors(19, 20), since it is these vagal receptors that are primarilysensitive to lung volume. Other, more rapidly adapting vagal receptorsare not felt to be likely candidates for mediating such activity,since they respond primarily to flow with only modest volume sensitivity(25). One plausible explanation for the reduction in TIn withincreasing flow rate in our experiments is, therefore, that ahigher flow rate results in an earlier attainment of the volumethreshold for inspiratory termination. To assess this possibilitywe determined the volume at which switching occurred (Vth), andplotted this against values of TIn observed at different flowrates (solid line, Figure 8). As can be seen in Figure 8, thispossibility can be immediately discounted. Rather than being higherat low TIn values (as would be expected with the H-B reflex [Figure8, dashed line]), the volume at switching was actually significantlylower at the highest flows rates relative to the volume valuesat lower flows, where TIn was longest. There are two possibleexplanations for this unexpected behavior as follows: (1). Theresponse observed in the present study was not related to thevolume-dependent H-B reflex, but represents a newly discovered,flow-specific response that is particularly prominent under theconditions of the present experiments. (2). A more provocativeexplanation is that the classical inspiratory inhibitory H-B reflexis mediated primarily, or to a considerable extent, by flow-sensitivereceptors, with the apparent volume dependence being largely fortuitous.The following observations are noteworthy in this respect: First,in all experiments in which the "volume threshold" for inspiratorytermination was determined, changes in VT were associated with,or produced by, concurrent changes in inspiratory flow (23,24). Second, when the increase in volume is sustained over severalbreaths, the effect on TIn is lost (26, 27); the loss of thiseffect occurs very rapidly (usually by the second breath [personalobservations]). This has been traditionally attributed to centraladaptation (17, 26, 28). Although the development of somecentral adaptation has been unequivocally demonstrated (28),the rapid loss of effect of volume on TIn could, at least in part,be related to an important contribution from flow-sensitive receptors;inspirations occurring at an increased but constant volume arenot subjected to the flow-related component of thereflex.

Our results do not permit a distinction between the two foregoing possibilities. Additional studies with animals are requiredto determine the specific contribution of flow to the inspiratoryterminating response associated with tidal changes in volume andflow. One earlier study that addressed this issue, and which showedno independent flow effect (29), was limited by the small flowrangetested.

Other Timing Responses

The response of TEn to changes in inspiratory flow was inconsistent and generally not significant (Figures 5 and 6B). It hasbeen previously shown in anesthetized animals that isolated reductionin TIn, produced by vagal (28) or pontine (30) stimulationlimited to inspiration, are associated with reductions in TEn.This indicates the presence of a central linkage between TIn andTEn. According to these findings in animals studies, we shouldhave seen significant reductions in TEn as a result of the reductionin TIn. It is possible that our failure to observe such reductionswas related to continued inflation during neural expiration, which,according to the H-B expiratory-prolonging reflex, would tendto lengthen TEn (17). The extent of continued inflation duringneural expiration in our experiments, expressed by $Delta$ Tend, variedwith inspiratory flow rate and showed an average biphasic relation(Figure 6E). There was a corresponding average biphasic TEn response(Figure 6B). To further investigate this possibility, we performedmultiple linear regression analysis to determine the factors thatcorrelated with changes in TEn ( $Delta$ TEn). The independent variablesselected for this analysis were $Delta$ Tend, $Delta$ TIn, and flow. The resultsfor all subjects were pooled. $Delta$ Tend had a highly significant independenteffect on TEn (p < 0.00001), with a coefficient of 1.2 indicatingthat an increase in $Delta$ T_end is associated with nearly the same increase(actually a slightly greater increase) in TEn. The change in TInalso had a significant independent effect (p = 0.01), but thecoefficient was surprisingly negative ( $-$ 0.5). This suggests thatrather than a reduction in TIn leading to a reduction TEn, theopposite occurs. It is possible that this negative correlationis related to errors in measurement of TIn; for a given Ttot,a given underestimation of TIn produces an overestimation of TEn,and vice versa. Additionally, flow had a significant effect (p= 0.004), independent of $Delta$ Tend and TIn. The coefficient was $-$ 0.34.The mechanism by which this effect may be exerted is not clear,and may be related to an increase in respiratory drive producedby increasing flow, as reported earlier (1).

That $Delta$ Tend exerts a strong influence on TEn is likely to explain the failure of the respiratory rate to increase when theflow rate is increased but VT is also increased to keep the ventilatorTI constant (4, 31). Under these conditions, the reductionin TIn produced by the increase in flow results in an equal increasein $Delta$ Tend with a corresponding lengthening of TEn. This would offsetthe effect of inspiratory shortening onTtot.

As a consequence of the continuous decrease in TIn with flow (Figure 6A) and the biphasic response of TEn (Figure 6B), TIn/Ttotwas independent of flow up to a flow rate of 1.5 L/s (Figure 6D).At higher flow rates, TIn/Ttot decreasedsharply.

The response of Ttot to an increasing flow rate (Figure 6C) was similar in magnitude to what was reported earlier over thecomparable flow range (up to 1.5 L/s [1-3]). The present studyshows that the response tends to saturate at a flow of approximately1.5 L/s (Figure 6C) despite further decreases in TIn.

Clinical Implications

The flow range used in this study (0.8 to 2.5 L/s) covers the range of flow requirements encountered in critically ill patientsreceiving mechanical ventilation (32). Our results show thatTIn and TIn/Ttot are quite sensitive to ventilator flow rate overthis clinically relevant range. We are not aware of any studiesin which the effect of ventilator flow on these variables wassystematically assessed in mechanically ventilated patients. Itis, however, almost certain that the responses observed here dooccur in the intensive care unit (ICU) setting. Thus, Corne andassociates recently reported that RR increases as a function offlow rate (at constant VT) in ventilator dependent patients (5).To the extent that the increase in RR is principally the resultof a reduction in TIn (current findings), such patients are likelyto display a dependence of TIn on flow. Furthermore, in severalunrelated published studies, some of the illustrations clearlyshow instances in which inspiratory effort terminated virtuallyimmediately after triggering (e.g., Figure 1, [33] and Figure3D [34]). Because this immediate termination represents the extremeof the TIn response observed in the current study, it is almostcertain that intermediate, less dramatic, responses also occurin the ICUsetting.

Given that the responses demonstrated in our study are likely to occur in ventilator-dependent patients, the following clinicalimplications may be inferred from our findings, although thesemust await direct confirmation before being applied clinically.

Marini and colleagues (35) and Ward and coworkers (36) found that the work of breathing is inversely related to ventilatorflow rate in the flow range below 1 L/s. The pressure-time product(time integral of Pmus per breath, PTP) was also found to decreasewith increasing flow in the flow range from 0.4 to 1.1 L/s (36).The results presented by these authors (35, 36) do not permitan assessment of the mechanisms responsible for this response.Our results suggest that a flow-dependent reflex termination ofTIn, with a consequent reduction in peak Pmus, may play an importantrole in this demonstratedunloading.
We have shown that neural TI/Ttot decreases significantly as flow rate increases (Figure 6D). TIn/Ttot is one of the two keyvariables determining inspiratory muscle energy consumption andendurance, the other variable being mean inspiratory muscle pressureduring the inspiratory phase (37). Our findings therefore indicatethat assessment of the impact of flow rate on inspiratory muscleenergetics must include an evaluation of the effect of flow onTI/TTOT, since this effect can besubstantial.
It is widely believed that flow rates in excess of 1 L/s do not result in further inspiratory muscle unloading. This is primarilybased on the results of Marini and colleagues (35), who reportedno reduction in the work of breathing (WOB) as flow was increasedfrom 1.0 to 1.6 L/s in ventilator-dependent patients. These authors,however, reported WOB in joules per liter. This index is essentiallya reflection of mean inspiratory muscle pressure over the durationof the ventilator's inflation phase (i.e., PTP/TI_vent). BecauseTI_vent decreases with increasing inspiratory flow, an unchangedWOB, expressed in joules/liter, signifies a commensurate reductionin PTP. Furthermore, the analysis done by Marini and colleaguesdid not consider the impact of flow on TIn/Ttot. It is possible,therefore, that the unloading effect of flow above 1 L/s was considerablyunderestimated in theirstudy.
In some patients, WOB remains quite excessive, even at a ventilator flow of 100 L/min (see Table 1 in Ref. 35). We have shownthat the effect of flow on TIn, and TIn/Ttot is continuous toat least a flow rate of 2.5 L/s (150 L/min). These findings suggestthat substantial further unloading may be achieved in such patientsat yet greater flow rates than are currently available on commercialventilators. This prediction, if experimentally confirmed, maylessen the frequent need for sedation or paralysis in suchpatients.
In an effort to rapidly attain target pressure in the PSV mode, some commercial ventilators deliver a high initial flow rate(1.0 to 1.5 L/s) even at low pressure settings (38, 39). Atlow PSV levels, such as may be applied in preparation for weaning,TI_vent and VT are substantially dependent on the duration andamplitude of the patient's effort (40). Should the initial flowrate continue to be high at these low PSV levels, and should thisresult in brief inspiratory efforts (as per our current findings),the result would be brief, shallow inspirations at low PSV levels.This may be interpreted as "weaning failure." The impact of suchbrief, weak efforts, maintained over a long period (days), onmuscle reconditioning in preparation for weaning, or on the abilityof the respiratory control system to resume a normal breathingpattern during a trial of spontaneous breathing, would also haveto beaddressed.

In summary, we have demonstrated the existence of a powerful, graded, flow-related inspiratory terminating reflex in normalsubjects. This reflex is sufficiently powerful as to be capableof reducing inspiratory effort to a mere triggering effort withinthe flow range encountered in critically ill patients. Accordingly,it may have implications for inspiratory muscle unloading andpatient-ventilator synchrony during mechanical ventilation. Theresponse is not related to earlier attainment of a volume-dependentthreshold for inspiratory termination, but is specific to flow.Although there is indirect evidence that this reflex is operativein ventilator-dependent patients, further studies are clearlyneeded to establish its gain under different circumstances andits clinicalsignificance.

	Footnotes

Correspondence and requests for reprints should be addressed to Dr. M. Younes, RS 311, Health Sciences Centre, 820 Sherbrook Street, Winnipeg, MB, R3A 1R9 Canada.

(Received in original form September 22, 1997 and in revised form August 13, 1998).

Dr. Fernandez was supported by FIS from the Spanish Health Ministry (BAE 95/5660).
Dr. Mendez was supported by a fellowship from the Manitoba LungAssociation.

Acknowledgments: Supported by the Medical Research Council of Canada and the Respiratory Health Network of Centers of Excellence(INSPIRAPLEX).

References

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

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