Effects of Different Expiratory Maneuvers on Inspiratory Muscle Force Output

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Effects of Different Expiratory Maneuvers on Inspiratory Muscle Force Output

SPYROS ZAKYNTHINOS, THEODOROS VASSILAKOPOULOS, ANTONIOS MAVROMMATIS, CHARIS ROUSSOS, and GEORGE E. TZELEPIS

Pulmonary Services and Intensive Care Units, Evangelismos Hospital and Onassis Cardiac Center; University of Athens Medical School, Athens, Greece; and Wayne State University, Detroit, Michigan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

We assessed the effects of two different expiratory maneuvers (fast [F] or slow [S]) on the ability of normal subjects (n= 12, age 35 ± 6 yr) to generate maximal inspiratory pressuresand maximal inspiratory flows near residual volume (RV). Withthe F maneuver, the subject exhaled rapidly to RV and immediatelyperformed a maximal inspiratory effort, whereas with the S maneuverthe subject exhaled slowly to RV, paused for 4 to 6 s at RV, andthen inspired forcefully. Maximal static inspiratory pressureagainst an occluded airway (PI_max), and maximal dynamic inspiratorypressure (PI_dyn) and maximal inspiratory flow ( $V$ I_max) with noadded resistance, as well as the electromyographic activity ofthe parasternal muscles, were measured during each maneuver. Bothmaneuvers were initiated from TLC and were performed randomly.In comparison with the S maneuver, the F maneuver yielded valuesof higher (mean ± SE) PI_max (148 ± 5 cm H₂O versus 135 ± 7 cmH₂O, p < 0.05), PI_dyn (33 ± 2 cm H₂O versus 28 ± 2 cm H₂O, p <0.05), and $V$ I_max (12.3 ± 0.4 L/s versus 11.4 ± 0.6 L/s, p <0.05). In addition, the rate of rise of PI_max, the rate of riseof PI_dyn, and the integrated peak electromyographic activity ofthe parasternal muscles were significantly greater with the Fthan with the S maneuver, suggesting greater inspiratory muscle(IM) activation. The enhanced IM activation may be related toa specific inspiratory-expiratory muscle interaction similar tothe agonist-antagonist interactions described for a pair of skeletalmuscles.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The force output of respiratory muscles generally depends on respiratory muscle mass, intrinsic contractility, mechanicaladvantage, operating length, and degree of neural activation ofthese muscles (1). In a recent study (2), we showed thatcertain maneuvers may significantly increase the pressure (force)output of the expiratory muscles. Specifically, the maximal dynamicexpiratory pressure generated during a forced expiration at TLCcan be significantly enhanced if expiratory muscle contractionis immediately preceded by a fast inspiratory muscle (IM) contraction,such as in rapid inspiration to TLC. In contrast, the maximaldynamic expiratory pressure at TLC is comparatively lower whenthe maneuver involves a slow inspiration to TLC and a breathholdprior to maximal expiration (2). Although not fully understood,the mechanism underlying the enhanced maximal dynamic expiratorypressure in the first of these situations appears to be an enhancedactivation of the agonist muscles related to a specific inspiratory-expiratoryinteraction analogous to those described for a pair of agonist-antagonist skeletal muscles (3).

In the study reported here, we reversed the sequence of agonist-antagonist contraction and examined the extent to which IMpressure output is similarly augmented by maneuvers in which IM(agonist) contraction is preceded by a fast contraction of theexpiratory (antagonist) muscles. To this end, we assessed theability of normal subjects to generate maximal inspiratory pressuresand maximal inspiratory flows against an occluded or unoccludedairway near RV following slow or fast expirations toRV.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Twelve laboratory volunteers (all men, age 35 ± 6 yr) participated in the study. The subjects were familiar with respiratorymaneuvers, and all but three were naive to the purpose of thestudy. No subject had a history of pulmonary disease; there werefive smokers, but they all had normal spirometric results. Thestudy was approved by the institutional reviewboard.

All experiments were performed with the subjects in the seated position. Pressure at the airway opening (Pao) was measuredwith a pressure transducer (MP-45, ± 250 mm Hg; Validyne Corp.,Northridge, CA) calibrated to 300 cm H₂O. Inspiratory flow wasmeasured with a heated pneumotachograph (Hans-Rudolph, KansasCity, MO) and a differential pressure transducer (MP-45, ± 2 cmH₂O; Validyne). Inspired volume was obtained by integrating (Gouldintegrator; Gould Instrument, Cleveland, OH) the flow signal.The electromyograph (EMG) of parasternal muscles was recordedthrough a pair of surface electrodes placed over the second orthird intercostal space near the right sternal margin. EMGs signalswere amplified (Nihon-Koden Co., Tokyo, Japan) and filtered, usinga bandpass between 20 Hz and 1 kHz. Raw EMG signals were rectifiedand integrated by a moving averager (MA-821 RSP; CWE Inc., Ardmore,PA), using a 200-ms averaging time. Pressure, flow, volume, andEMG signals were displayed on a monitor (Gould V1000 video display).All signals were digitized in real time, recorded on a strip chartrecorder (Gould ES 1000), and stored in a computer (Wyse 486)for lateranalysis.

Maximal static inspiratory pressure (PI_max) against an occluded airway (Mueller maneuver), and maximal dynamic inspiratorypressure (PI_dyn) and maximal inspiratory flow ( $V$ I_max) with noexternal resistance, were measured near RV in all subjects, usingtwo different (fast [F] or slow [S]) maneuvers. With the F maneuver,the subject exhaled rapidly to RV and immediately performed aforceful inspiration, whereas in the S maneuver, the subject exhaledslowly to RV, held the breath at RV for about 4 to 6 s, and theninspired forcefully against the resistance. During Mueller maneuvers,a 14-gauge needle was inserted into the mouthpiece of the respirometerto prevent contraction of the buccal muscles. During efforts withan unoccluded airway, the lung volume at which measurements weremade was assessed from inspiratory VC values, which were obtainedby having the subject fully inspire to TLC. Prior to measurements,all subjects performed several practice runs for each maneuver.Both occluded and unoccluded maneuvers were initiated from TLC,and the two types of maneuver were interspersed randomly withone another. During these efforts, care was taken to maintainthe subject's neck in a neutral position in order to decreaseflow variability related to tracheal collapsibility (4). Eachsubject performed from five to seven repeats of each maneuverwith and without resistance, with a frequency of one run every2 to 3min.

The digitized data were analyzed with the Labdat software program. Integrated EMG signals were analyzed for peak EMG activity;the rate of increase of Pao (dPao/dt) was analyzed by differentiatingthe pressure waveform. Efforts for a given maneuver were acceptedif they were within 5% of maximum VC; of those that met this criterion,the three or four runs with the greatest Pao values were analyzed.Average values of three or four measurements were used for analysis.Grouped data were analyzed with Student's t test for paired variables,and were reported as Mean ± SE. A value of p $=<$ 0.05 was consideredsignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Complete EMG data were available for nine subjects. Figure 1 shows typical maneuvers from which the data were obtained. Withthe F maneuver, duration of expiration was comparable (p > 0.05)for efforts with occluded airway and those with no added resistance(2.75 ± 0.25 s versus 2.53 ± 0.21 s, respectively); similarly,with the S maneuver, duration of expiration did not differ betweenefforts with an occluded airway and those with no added resistance(7.87 ± 0.57 s versus 8.54 ± 0.58 s, respectively).

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Figure 1. Representative tracings obtained with the F and S expiratory maneuvers during maximal inspiratory efforts with an occluded airway near RV in one subject. The solid vertical line marks the beginning of expiration and the dotted vertical line passes through the beginning of inspiration. Pao = pressure at the airway opening; EMGp = electromyograph of parasternal muscles.

During Mueller maneuvers, PI_max, dPI_max/dt, and peak EMG activity of the parasternal muscles were all greater (p < 0.05) withthe F than with the S maneuver (Table 1). During efforts withno added resistance, PI_dyn, $V$ I_max, dPI_dyn/dt, and peak EMG activityof the parasternal muscles were similarly greater with the F (p< 0.05) than with the S maneuver (Table 1).

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TABLE 1

PARAMETERS OBTAINED WITH THE FAST AND SLOW MANEUVERS

The percent intermaneuver increase in variables at each resistance is shown in Figure 2. The percent increase in dPao/dt withF was significantly greater for efforts with no added resistance(p < 0.05) than for those with an occluded airway.

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Figure 2. Percent increase in parameters obtained with the F maneuver during maximal inspiratory efforts with an occluded or unoccluded airway in all subjects. The ordinate represents the percent increase with the F maneuver in comparison with the S maneuver. Data are in mean ± SE. (*p < 0.05). Pao = pressure at the airway opening, EMGp = electromyograph of parasternal muscles.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

We found that the ability of normal volunteers to generate pressure and flow at RV was significantly enhanced with maneuversin which forceful inspiration was immediately preceded by a fastexpiration. This enhanced capacity appears to be related to greaterIM activation, as shown by the EMG activity of parasternalmuscles.

In a recent study (2), we showed that the activation and force output of expiratory muscles at TLC was substantially enhancedwhen forced expiration was immediately preceded by fast inspirationswithout an end-inspiratory pause, as compared with slow inspirationand a breathhold lasting a few seconds at TLC. Identical maneuvershave also been found to be associated with significantly greaterpeak expiratory flows in both normal subjects (5, 6) andpatients with respiratory disease (7, 8). This enhancedcapacity was attributed to a specific inspiratory-expiratory muscleinteraction analogous to those described in skeletal muscle fora pair of agonist-antagonist muscles. The present findings extendour previous work (2) to include a similar interaction nearRV, thus establishing the bidirectional character of the inspiratory-expiratorymuscle interaction. In fact, the intermaneuver differences inPI_dyn (19%) and $V$ I_max (9%) attained near RV are roughly in thesame range as respective values for maximal dynamic expiratorypressure (17%) and expiratory flow (7%) obtained atTLC.

We paid special attention to conducting the measurements in the present study at similar lung volumes for both the F and Smaneuvers. However, VC values measured during efforts with anunoccluded airway showed that the operating lung volume was greater(by approximately 300 ml) with the F than that with the S maneuver.Likewise, for efforts with an occluded airway, we estimate thatthe lung volume with the F maneuver was also greater than thatwith the S maneuver and by a similar amount, as shown by expiratoryVC values (corrected for gas compression) and the comparable expiratorytimes. Given the shape of the volume-pressure relationship nearRV, such differences in lung volume probably do not have any substantialeffect on generated pressures and, if anything, would tend tounderestimate pressures obtained with the Fmaneuver.

Our dPao/dt and EMG data clearly show that the greater IM pressure generation with forceful inspiration immediately precededby fast expiration is related to increased muscle activation withthis F maneuver. The precise mechanism underlying this enhancementis not quite known, and has previously been discussed (2).Briefly, the enhanced activation may be related to the conditioningcontraction of the antagonist (expiratory) muscles, which immediatelyprecedes agonist (inspiratory) muscle contraction. This interactionhas recently been described in peripheral muscles, and studiessuggest that the intensity of conditioning contraction is likelyto influence agonist motor-unit activation (3). Alternatively,the intensity of contraction may be related to a pliometric (lengthening)contraction of the IM during expiration, which was followed immediatelyby a concentric contraction. IM pressure output under these conditionsis expected to be greater than that occurring during pure concentriccontraction (9). Evidence for an active contraction of thediaphragm during forced expiration was previously provided byMelissinos and coworkers in normal subjects (12). However, inthe absence of measurements of transdiaphragmatic pressure anddiaphragmatic EMG, our present design does not allow us eitherto elucidate the precise mechanism for the increased muscle activationthat we found with the F maneuver or to partition increments ofIM pressure between the diaphragm and rib cage muscles. Recentstudies with normal volunteers showed that the diaphragm is poorlyactivated near RV (13, 14). The extent to which fast expiratorymaneuvers actually augment voluntary diaphragmatic activationin this region awaits furtherstudy.

Figure 2 shows intermaneuver differences in the degree of IM activation and pressure generation between efforts against anoccluded airway and those with no added resistance. With the Fmaneuver, there was a trend toward greater muscle activation andpressure generation (about twofold) for efforts with no addedresistance than for those against an occluded airway. Althoughthe mechanism underlying this difference has yet to be defined,it may be due to differences in reflex inhibition (15).

Our data may have implications for accurately measuring IM muscle strength and $V$ I_max in clinical and epidemiologic studies.PI_max, a widely used indicator of IM strength (16), is usuallymeasured at RV, since patients find the maneuver much easier atRV than at FRC. Likewise, $V$ I_max is an important component ofthe flow-volume loop and is frequently used (in conjunction withmaximum expiratory flow) in screening patients for upper airwayobstruction. Given that expiratory speed influences both measurements,a standardization of the maneuver in which they are measured maydecrease the variability of both PI_max and $V$ I_max obtained atRV (17, 18). Furthermore, the enhanced activation of IM withthe F maneuver as used in our study could in theory be used intraining protocols to increase IM strength (19). In our previousstudy (20) of IM training at various lung volumes, the greaterposttraining increase in IM strength at RV than at FRC or at highlung volumes may have been related to a similar agonist-antagonistinteraction. However, the clinical application of this trainingtechnique may be limited by a greater likelihood of muscle injurywith the F maneuver (19).

In conclusion, the present study indicates that the ability of normal subjects to generate maximal inspiratory pressures andflows near RV can be significantly enhanced by maneuvers in whichforceful inspiration is immediately preceded by a fast expiration.In contrast, slow expirations to RV, with a pause of a few secondsat RV, generate comparatively lower pressure and flows. Thesedata suggest an expiratory-inspiratory muscle interaction similarto those described for pairs of agonist-antagonist skeletal muscles,and in conjunction with analogous data obtained previously atTLC, establish the bidirectional character of this respiratorymuscleinteraction.

	Footnotes

Supported in part by a grant for Scientific Development in Greece (PENED 95/ 773/3/3001 and the Thorax Foundation.

Correspondence and requests for reprints should be addressed to George E. Tzelepis, M.D., John D. Dingell VAMC, 4646 John R. Road, Detroit, MI 48201. E-mail: gtzelepis{at}intmed.wayne.edu

(Received in original form July 2, 1998 and in revised form September 28, 1998).

Acknowledgments: The authors thank Drs. J. Milic-Emili and F. G. Hoppin, Jr. for usefuldiscussions.

References

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RESULTS
DISCUSSION
REFERENCES

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