Kinematics and mechanics of midcostal diaphragm of dog

Boriek, Aladin M., Joseph R. Rodarte, and Theodore A. Wilson. Kinematics and mechanics of midcostal diaphragm of dog. J. Appl. Physiol. 83(4):1068-1075, 1997.Radiopaque markers were attached to theperitoneal surface of three neighboring muscle bundles in the midcostaldiaphragm of four dogs, and the locations of the markers were trackedby biplanar video fluoroscopy during quiet spontaneous breathing andduring inspiratory efforts against an occluded airway at three lungvolumes from functional residual capacity to total lung capacity inboth the prone and supine postures. Length and curvature of the musclebundles were determined from the data on marker location. Musclelengths for the inspiratory states, as a fraction of length atfunctional residual capacity, ranged from 0.89 ± 0.04 at endinspiration during spontaneous breathing down to 0.68 ± 0.07 duringinspiratory efforts at total lung capacity. The muscle bundles werefound to have the shape of circular arcs, with the three bundlesforming a section of a right circular cylinder. With increasing lungvolume and diaphragm displacement, the circular arcs rotate around theline of insertion on the chest wall, the arcs shorten, but the radiusof curvature remains nearly constant. Maximal transdiaphragmaticpressure was calculated from muscle curvature and maximaltension-length data from the literature. The calculated maximaltransdiaphragmatic pressure-length curve agrees well with the data ofRoad et al. (J. Appl. Physiol. 60:63-67, 1986).

     

Contractions of specific abdominal muscles in postural tasks are affected by respiratory maneuvers

Hodges, Paul W., Simon C. Gandevia, and Carolyn A. Richardson. Contractions of specific abdominalmuscles in postural tasks are affected by respiratory maneuvers.J. Appl. Physiol. 83(3): 753-760, 1997.The influence of respiratory activity of the abdominal muscleson their reaction time in a postural task was evaluated. Theelectromyographic (EMG) onsets of the abdominal muscles and deltoidwere evaluated in response to shoulder flexion initiated by a visualstimulus occurring at random throughout the respiratory cycle.Increased activity of the abdominal muscles was produced by inspiratoryloading, forced expiration below functional residual capacity, and astatic glottis-closed expulsive maneuver. During quiet breathing, thelatency between activation of the abdominal muscles and deltoid was notinfluenced by the respiratory cycle. When respiratory activity of theabdominal muscles increased, the EMG onset of transversus abdominis andinternal oblique, relative to deltoid, was significantly earlier formovements beginning in expiration, compared with inspiration [by97-107 ms (P < 0.01) and64-90 ms (P < 0.01),respectively]. However, the onset of transversus abdominis EMGwas delayed by 31-54 ms (P < 0.01) when movement was performed during a static expulsive effort,compared with quiet respiration. Thus changes occur in earlyanticipatory contraction of transversus abdominis during respiratorytasks but they cannot be explained simply by existing activation of themotoneuron pool.

     

Analysis of human chest wall motion using a two-compartment rib cage model.

We present a model of chest wall mechanics that extends the model described previously by Macklem et al. (J. Appl. Physiol. 55: 547-557, 1983) and incorporates a two-compartment rib cage. We divide the rib cage into that apposed to the lung (RCpul) and that apposed to the diaphragm (RCab). We apply this model to determine rib cage distortability, the mechanical coupling between RCpul and RCab, the contribution of the rib cage muscles to the pressure change during spontaneous inspiration (Prcm), and the insertional component of transdiaphragmatic pressure in humans. We define distortability as the relationship between distortion and transdiaphragmatic pressure (Pdi) and mechanical coupling as the relationship between rib cage distortion and the pressure acting to restore the rib cage to its relaxed configuration (Plink), as assessed during bilateral transcutaneous phrenic nerve stimulation. Prcm was calculated at end inspiration as the component of the pressure displacing RCpul not accounted for by Plink or pleural pressure. Prcm and Plink were approximately equal during quiet breathing, contributing 3.7 and 3.3 cmH2O on average during breaths associated with a change in Pdi of 3.9 cmH2O. The insertional component of Pdi was measured as the pressure acting on RCab not accounted for by the change in abdominal pressure during an inspiration without rib cage distortion and was 40 +/- 12% (SD) of total Pdi. We conclude that there is substantial resistance of the human rib cage to distortion, that, along with rib cage muscles, contributes importantly to the fall in pleural pressure over the costal surface of the lung.     

Chest wall motion during tidal breathing

De Groote, A., M. Wantier, G. Cheron, M. Estenne, and M. Paiva. Chest wall motion during tidal breathing. J. Appl. Physiol. 83(5): 1531-1537, 1997.We have used an automaticmotion analyzer, the ELITE system, to study changes inchest wall configuration during resting breathing in five normal,seated subjects. Two television cameras were used to record thex-y-z displacements of 36 markers positioned circumferentiallyat the level of the third (S₁) and fifth(S₂) costal cartilage, corresponding to the lung-apposedrib cage; midway between the xyphoid process and thecostal margin (S₃), corresponding to the abdomen-apposedrib cage; and at the level of the umbilicus (S₄).Recordings of different subsets of markers were made by submitting thesubject to five successive rotations of 45-90°. Each recordinglasted 30 s, and three-dimensional displacements of markers wereanalyzed with the Matlab software. At spontaneous end expiration,sections S_1-3 were elliptical but S₄ wasmore circular. Tidal changes in chest wall dimensions were consistentamong subjects. For S_1-2, changes during inspirationoccurred primarily in the cranial and ventral directions and averaged3-5 mm; displacements in the lateral direction were smaller(1-2 mm). On the other hand, changes at the level ofS₄ occurred almost exclusively in the ventral direction. Inaddition, both compartments showed a ventral displacement of theirdorsal aspect that was not accounted for by flexion of the spine. Weconclude that, in normal subjects breathing at rest in the seatedposture, displacements of the rib cage during inspiration are in thecranial, lateral outward, and ventral directions but that expansion ofthe abdomen is confined to the ventral direction.

     

Phrenic motoneuron discharge during sustained inspiratory resistive loading

Iscoe, Steve. Phrenic motoneuron discharge duringsustained inspiratory resistive loading. J. Appl.Physiol. 81(5): 2260-2266, 1996.I determinedwhether prolonged inspiratory resistive loading (IRL) affects phrenicmotoneuron discharge, independent of changes in chemical drive. Inseven decerebrate spontaneously breathing cats, the discharge patternsof eight phrenic motoneurons from filaments of one phrenic nerve weremonitored, along with the global activity of the contralateral phrenicnerve, transdiaphragmatic pressure, and fractional end-tidalCO₂ levels. Discharge patterns during hyperoxic CO₂ rebreathingand breathing against an IRL (2,500-4,000cmH₂O ^· l^{1 ·} s)were compared. During IRL, transdiaphragmatic pressure increased andthen either plateaued or decreased. At the highest fractional end-tidalCO₂ common to both runs,instantaneous discharge frequencies in six motoneurons were greaterduring sustained IRL than during rebreathing, when compared at the sametime after the onset of inspiration. These increased dischargefrequencies suggest the presence of a load-induced nonchemical drive tophrenic motoneurons from unidentified source(s).

     

Superior laryngeal nerve section alters responses to upper airway distortion in sleeping dogs

Curran, Aidan K., Peter R. Eastwood, Craig A. Harms, CurtisA. Smith, and Jerome A. Dempsey. Superior laryngeal nerve sectionalters responses to upper airway distortion in sleeping dogs.J. Appl. Physiol. 83(3): 768-775, 1997.We investigated the effect of superior laryngeal nerve (SLN)section on expiratory time(TE) and genioglossuselectromyogram (EMGgg) responses to upper airway (UA) negative pressure(UANP) in sleeping dogs. The same dogs used in a similar intact study(C. A. Harms, C. A., Y.-J. Zeng, C. A. Smith, E. H. Vidruk, and J. A. Dempsey. J. Appl. Physiol. 80:1528-1539, 1996) were bilaterally SLN sectioned. After recovery,the UA was isolated while the animal breathed through a tracheostomy.Square waves of negative pressure were applied to the UA from below thelarynx or from the mask (nares) at end expiration and held until thenext inspiratory effort. Section of the SLN increased eupneicrespiratory frequency and minute ventilation. Relative to the same dogsbefore SLN section, sublaryngeal UANP caused lessTE prolongation while activation of the genioglossus required less negative pressures. Mask UANP had noeffect on TE or EMGgg activity.We conclude that the SLN 1) is notobligatory for the reflex prolongation ofTE and activation of EMGggactivity produced by UANP and 2)plays an important role in the maintenance of UA stability and thepattern of breathing in sleeping dogs.

     

Laryngeal and abdominal muscle electrical activity during periodic breathing in nonsedated lambs

Kianicka, Irenej, Véronique Diaz, Sylvain Renolleau,Emmanuel Canet, and Jean-Paul Praud. Laryngeal and abdominal muscle electrical activity during periodic breathing in nonsedated lambs. J. Appl. Physiol. 84(2):669-675, 1998.We recently reported that glottic closure waspresent throughout central apneas in awake lambs. The present studytested whether glottic closure was also observed during periodicbreathing (PB). We attempted to induce PB in 21 nonsedated lambs onreturn from hypocapnic hypoxia to room air. Airflow and thyroarytenoid(a laryngeal constrictor, n = 16),cricothyroid (a laryngeal dilator, n = 10), and abdominal (n = 9) muscleelectrical activity (EMG) were monitored continuously. PB was observedin 16 lambs, with apneic phases in 8 lambs. Thyroarytenoid muscle EMGwas observed at the nadir of PB, either throughout apnea or withprolonged expiration during the lowest respiratory efforts. Phasicinspiratory cricothyroid muscle EMG and phasic expiratory abdominal EMGdisappeared at the nadir of PB. Active glottic closure at the nadir ofPB, without abdominal muscle contraction, could be a beneficialmechanism, preserving alveolar gas stores for continuing gas exchangeduring the apneic/hypopneic phase of PB. However, consequences ofactive glottic closure on ventilatory instability, either enhancing orreducing, are unknown.

     

Lateral pharyngeal fat pad pressure during breathing in anesthetized pigs

Winter, W. Christopher, Tom Gampper, Spencer B. Gay, andPaul M. Suratt. Lateral pharyngeal fat pad pressure during breathing in anesthetized pigs. J. Appl.Physiol. 83(3): 688-694, 1997.It has beenhypothesized that the pressure in tissues surrounding the upper airwayis one of the determinants of the size and shape of the upper airway.To our knowledge, this pressure has not been measured. The purpose ofthis study was to test whether the pressure in a tissue lateral to theupper airway, the lateral pharyngeal fat pad pressure (Pfp), differsfrom atmospheric and pharyngeal pressures and whether it changes withbreathing. We studied six male lightly sedated pigs by inserting atransducer tipped catheter into their fat pad space by usingcomputerized tomographic scan guidance. We measured airflow with apneumotachograph attached to a face mask and pharyngeal pressure with aballoon catheter. Pfp differed from atmospheric pressure, generallyexceeding it, and from pharyngeal pressure. Pfp correlated positivelywith airflow and with pharyngeal pressure, decreasing duringinspiration and increasing during expiration. Changes in Pfp withventilation were eliminated by oropharyngeal intubation. We concludethat Pfp differs from atmospheric and pharyngeal pressures and that itchanges with breathing.

     

Respiratory tissue properties derived from flow transfer function in healthy humans

Tomalak, W., R. Peslin, and C. Duvivier. Respiratorytissue properties derived from flow transfer function in healthy humans. J. Appl. Physiol. 82(4):1098-1106, 1997.Assuming homogeneity of alveolar pressure, therelationship between airway flow and flow at the chest during forcedoscillation at the airway opening [flow transfer function(FTF)] is related to lung and chest wall tissue impedance (Zti):FTF = 1 + Zti/Zg, where Zg is alveolar gas impedance, which isinversely proportional to thoracic gas volume. By using a flow-typebody plethysmograph to obtain flow rate at body surface, FTF has beenmeasured at oscillation frequencies (f_os) of 10, 20, 30 and 40 Hz in eight healthy subjects during both quiet and deepbreathing. The data were corrected for the flow shunted through upperairway walls and analyzed in terms of tissue resistance (Rti) andeffective elastance (Eti,eff) by using plethysmographically measuredthoracic gas volume values. In most subjects, Rti was seen to decreasewith increasingf_os and Eti,effto vary curvilinearly withf_os²,which is suggestive of mechanical inhomogeneity. Rti presented a weakvolume dependence during breathing, variable in sign according tof_os and amongsubjects. In contrast, Eti,eff usually exhibited a U-shaped patternwith a minimum located a little above or below functional residualcapacity and a steep increase with decreasing or increasing volume(30-80 hPa/l²) on eitherside. These variations are in excess of those expected from the sigmoidshape of the static pressure-volume curve and may reflect the effect ofrespiratory muscle activity. We conclude that FTF measurement is aninteresting tool to study Rti and Eti,eff and that these parametershave probably different physiological determinants.

     

Air entry in infant resuscitation: oral or nasal routes?

Wilson-Davis, S. L., S. L. Tonkin, and T. R. Gunn. Air entry in infant resuscitation: oral ornasal routes?. J. Appl. Physiol.82(1): 152-155, 1997.The current recommendation for resuscitation of infants is to blow air into both the nose and mouth.We have observed that mothers cannot cover both the nose and mouth oftheir infants. We compared postmortem tracheal and esophageal air entryby using the nose, combined nose and mouth, and mouth routes in eightinfants. Air entry into the trachea occurred at lower pressures(P < 0.05) via a nose mask than via a combined nose and mouth mask or via a mouth mask. Air entry into thetrachea occurred at lower pressures (P < 0.05) via the nose route in the neutral and extended neck positionscompared with the flexed position. We were unable to demonstrate aneffect of the route of air entry on esophageal air entry. The findings indicate that the nasal route of air entry is more effective than thecombined nose and mouth or mouth routes and that neck flexion impedesair entry. We recommend that parents are taught to blow air into theirinfants' noses if the infant stops breathing.

     

Arousal pattern following central and obstructive breathing abnormalities in infants and children

McNamara, Frances, Faiq G. Issa, and Colin E. Sullivan.Arousal pattern following central and obstructive breathing abnormalities in infants and children. J. Appl.Physiol. 81(6): 2651-2657, 1996.We analyzed thepolysomnographic records of 15 children and 20 infants with obstructivesleep apnea (OSA) to examine the interaction between central andobstructive breathing abnormalities and arousal from sleep. Eachpatient was matched for age with an infant or child who had no OSA. Wefound that the majority of respiratory events in infants and childrenwas not terminated with arousal. In children, arousals terminated 39.3 ± 7.2% of respiratory events during quiet sleep and 37.8 ± 7.2% of events during active (rapid-eye-movement) sleep. In infants,arousals terminated 7.9 ± 1.0% of events during quiet sleep and7.9 ± 1.2% of events during active sleep. In both infants andchildren, however, respiratory-related arousals occurred more frequently after obstructive apneas and hypopneas than after central events. Spontaneous arousals occurred in all patients with OSA duringquiet and active sleep. The frequency of spontaneous arousals was notdifferent between children with OSA and their matched controls. Duringactive sleep, however, infants with OSA had significantly fewerspontaneous arousals than did control infants. We conclude that arousalis not an important mechanism in the termination of respiratory eventsin infants and children and that electroencephalographic criteria arenot essential to determine the clinical severity of OSA in thepediatric population.

     

Recovery of diaphragmatic function in awake sheep after two approaches to thoracic surgery

Imanaka, Hideaki, William R. Kimball, John C. Wain, MasajiNishimura, Kenichi Okubo, Dean Hess, and Robert M. Kacmarek. Recovery of diaphragmatic function in awake sheep after two approaches to thoracic surgery. J. Appl.Physiol. 83(5): 1733-1740, 1997.Video-assistedthoracoscopic surgery (VATS) is replacing thoracotomy, but no study hasaddressed the extent or duration of VATS-induced diaphragmaticalteration. We hypothesized that VATS would impair diaphragmaticfunction less and return diaphragmatic function faster thanthoracotomy. In eight sheep, sonomicrometers were randomly implanted onthe right costal diaphragm via VATS or thoracotomy. Diaphragmaticresting length, shortening fraction, and respiratory function weremeasured weekly during quiet breathing (QB) andCO₂ rebreathing for 4 wk. ForVATS, shortening fraction was smallest onpostoperative days 1 (POD 1) (6.4 ± 3.4 and12.9 ± 8.7% during QB and 10%CO₂ rebreathing, respectively) and7 (6.3 ± 3.4 and 16.9 ± 4.0%during QB and 10% CO₂rebreathing, respectively) and recovered by 3 wk (13.2 ± 1.8 and28.9 ± 8.0% during QB and 10%CO₂ rebreathing, respectively).For thoracotomy, shortening fraction at 10%CO₂ rebreathing was smaller onPODs 1, 7, 14 (15.9 ± 7.1, 13.6 ± 5.4, and 19.0 ± 6.9%) than onPOD 28 (29.9 ± 8.2%), but notduring QB on POD 1 or7 (7.5 ± 3.8 and 3.4 ± 2.6%)compared with POD 28 (10.7 ± 8.7%). Shortening fraction did not differ between surgeries. There wasno group difference in minute ventilation, respiratory rate,transdiaphragmatic pressure, or esophageal and gastric pressures. Inconclusion, although shortening fraction recovered faster for VATS,this translated into insignificant functional differences.

     

Hypoxic ventilatory sensitivity in men is not reduced by prolonged hyperoxia (Predictive Studies V and VI)

Gelfand, R., C. J. Lambertsen, J. M. Clark, and E. Hopkin.Hypoxic ventilatory sensitivity in men is not reduced by prolongedhyperoxia (Predictive Studies V and VI). J. Appl.Physiol. 84(1): 292-302, 1998.Potential adverseeffects on the O₂-sensing functionof the carotid body when its cells are exposed to toxic O₂ pressures were assessed duringinvestigations of human organ tolerance to prolonged continuous andintermittent hyperoxia (Predictive Studies V and VI). Isocapnic hypoxicventilatory responses (HVR) were determined at 1.0 ATA before and aftersevere hyperoxic exposures: 1)continuous O₂ breathing at 1.5, 2.0, and 2.5 ATA for 17.7, 9.0, and 5.7 h and2) intermittentO₂ breathing at 2.0 ATA (30 minO₂-30 min normoxia) for 14.3 O₂ h within 30-h total time. Postexposure curvature of HVR hyperbolas was not reduced compared withpreexposure controls. The hyperbolas were temporarily elevated tohigher ventilations than controls due to increments in respiratory frequency that were proportional toO₂ exposure time, notO₂ pressure. In humans, prolongedhyperoxia does not attenuate the hypoxia-sensing function of theperipheral chemoreceptors, even after exposures that approach limits ofhuman pulmonary and central nervous system O₂ tolerance. Current applicationsof hyperoxia in hyperbaric O₂therapy and in subsea- and aerospace-related operations are guided byand are well within these exposure limits.

     

Cerebral areas associated with motor control of speech in humans

Murphy, K., D. R. Corfield, A. Guz, G. R. Fink, R. J. S. Wise, J. Harrison, and L. Adams. Cerebral areas associated withmotor control of speech in humans. J. Appl.Physiol. 83(5): 1438-1447, 1997.We have definedareas in the brain activated during speaking, utilizing positronemission tomography. Six normal subjects continuously repeated thephrase "Buy Bobby a poppy" (requiring minimal languageprocessing) in four ways: A) spoken aloud, B) mouthed silently,C) without articulation, andD) thought silently. Statisticalcomparison of images from conditions Awith C andB withD highlighted areas associated witharticulation alone, because control of breathing for speech wascontrolled for; we found bilateral activations in sensorimotor cortexand cerebellum with right-sided activation in the thalamus/caudate nucleus. Contrasting images from conditionsA with B andC with D highlighted areas associated withthe control of breathing for speech, vocalization, and hearing, becausearticulation was controlled for; we found bilateral activations insensorimotor and motor cortex, close to but distinct from theactivations in the preceding contrast, together with activations inthalamus, cerebellum, and supplementary motor area. In neithersubtraction was there activation in Broca's area. These resultsemphasize the bilaterality of the cerebral control of "speaking"without language processing.

     

Muscle fiber architecture of the dog diaphragm

Boriek, Aladin M., Charles C. Miller III, and Joseph R. Rodarte. Muscle fiber architecture of the dog diaphragm.J. Appl. Physiol. 84(1): 318-326, 1998.Previous measurements of muscle thickness and length ratio ofcostal diaphragm insertions in the dog (A. M. Boriek and J. R. Rodarte.J. Appl. Physiol. 77: 2065-2070,1994) suggested, but did not prove, discontinuous muscle fiberarchitecture. We examined diaphragmatic muscle fiber architecture usingmorphological and histochemical methods. In 15 mongrel dogs, transversesections along the length of the muscle fibers were analyzedmorphometrically at ×20, by using the BioQuant System IVsoftware. We measured fiber diameters, cross-sectional fiber shapes,and cross-sectional area distributions of fibers. We also determinednumbers of muscle fibers per cross-sectional area and ratio ofconnective tissue to muscle fibers along a course of the muscle fromnear the chest wall (CW) to near the central tendon (CT) for midcostalleft and right hemidiaphragms, as well as ventral, middle, and dorsalregions of the left costal hemidiaphragm. In six other mongrel dogs,the macroscopic distribution of neuromuscular junctions (NMJ) onthoracic and abdominal diaphragm surfaces was determined by stainingthe intact diaphragmatic muscle for acetylcholinesterase activity. Theaverage major diameter of muscle fibers was significantly smaller, andthe number of fibers was significantly larger midspan between CT and CWthan near the insertions. The ratio of connective tissues to musclefibers was largest at CW compared with other regions along the lengthof the muscle. The diaphragm is transversely crossed by multiplescattered NMJ bands with fairly regular intervals offset in adjacentstrips. Muscle fascicles traverse two to five NMJ, consistent withfibers that do not span the entire fascicle from CT to CW. Theseresults suggest that the diaphragm has a discontinuous fiberarchitecture in which contractile forces may be transmitted among themuscle fibers through the connective tissue adjacent to the fibers.

     

Respiratory effort sensation during exercise with induced expiratory-flow limitation in healthy humans

Kayser, Bengt, Pawel Sliwinski, Sheng Yan, Mirek Tobiasz,and Peter T. Macklem. Respiratory effort sensation during exercisewith induced expiratory-flow limitation in healthy humans. J. Appl. Physiol. 83(3): 936-947, 1997.Nine healthy subjects (age 31 ± 4 yr) exercised with andwithout expiratory-flow limitation (maximal flow ~1 l/s). Wemonitored flow, end-tidal PCO₂, esophageal (Pes) and gastric pressures, changes in end-expiratory lungvolume, and perception (sensation) of difficulty in breathing. Subjectscycled at increasing intensity (+25 W/30 s) until symptom limitation.During the flow-limited run, exercise performance was limited in allsubjects by maximum sensation. Sensation was equally determined byinspiratory and expiratory pressure changes. In both runs, 90% of thevariance in sensation could be explained by the Pes swings (differencebetween peak inspiratory and peak expiratory Pes). End-tidalPCO₂ did not explain any variance insensation in the control run and added only 3% to the explained variance in the flow-limited run. We conclude that in healthy subjects,during normal as well as expiratory flow-limited exercise, the pleuralpressure generation of the expiratory muscles is equally related to theperception of difficulty in breathing as that of the inspiratorymuscles.

     

Respiratory-related pharyngeal constrictor muscle activity in decerebrate cats

Kuna, Samuel T., and Christi R. Vanoye.Respiratory-related pharyngeal constrictor muscle activity indecerebrate cats. J. Appl. Physiol.83(5): 1588-1594, 1997.Respiratory-related activity of thehyopharyngeus (middle pharyngeal constrictor) and thyropharyngeus(inferior pharyngeal constrictor) muscles was determined indecerebrate, tracheotomized adult cats and compared with theelectromyographic activity of the thyroarytenoid, a vocal cordadductor. During quiet breathing, the hyopharyngeus and usually thethyroarytenoid exhibited phasic activity during expiration and tonicactivity throughout the respiratory cycle. Respiratory-related thyropharyngeus activity was absent under these conditions. Progressive hyperoxic hypercapnia and progressive isocapnic hypoxia increased phasic expiratory activity in both pharyngeal constrictor (PC) musclesbut tended to suppress thyroarytenoid activity. Passively inducedhypocapnia and the central apnea that followed the cessation of themechanical hyperventilation were associated with tonic activation ofthe hyopharyngeus and thyroarytenoid but no recruitment inthyropharyngeus activity. The expiratory phase of a sigh and progressive pneumothorax were associated with an increase in phasic thyroarytenoid activity but no change in phasic PC activity. The results indicate that a variety of stimuli modulate respiratory-related PC activity, suggesting that the PC muscles may have a role in theregulation of upper airway patency during respiration.

     

Effect of prior O2 breathing on ventilatory response to sustained isocapnic hypoxia in adult humans

Honda, Y., H. Tani, A. Masuda, T. Kobayashi, T. Nishino, H. Kimura, S. Masuyama, and T. Kuriyama. Effect of priorO₂ breathing on ventilatoryresponse to sustained isocapnic hypoxia in adult humans.J. Appl. Physiol. 81(4):1627-1632, 1996.Sixteen healthy volunteers breathed 100%O₂ or room air for 10 min in random order, then their ventilatory response to sustained normocapnic hypoxia (80% arterial O₂saturation, as measured with a pulse oximeter) was studied for 20 min.In addition, to detect agents possibly responsible for the respiratorychanges, blood plasma of 10 of the 16 subjects was chemically analyzed.1) Preliminary O₂ breathing uniformly andsubstantially augmented hypoxic ventilatory responses.2) However, the profile ofventilatory response in terms of relative magnitude, i.e., biphasichypoxic ventilatory depression, remained nearly unchanged.3) Augmented ventilatory incrementby prior O₂ breathing wassignificantly correlated with increment in the plasma glutamine level.We conclude that preliminary O₂administration enhances hypoxic ventilatory response without affectingthe biphasic response pattern and speculate that the excitatory aminoacid neurotransmitter glutamate, possibly derived from augmentedglutamine, may, at least in part, play a role in this ventilatoryenhancement.

     

Chest wall distortion during resistive inspiratory loading

We studied six (1 naive and 5 experienced) subjects breathing with added inspiratory resistive loads while we recorded chest wall motion (anteroposterior rib cage, anteroposterior abdomen, and lateral rib cage) and tidal volumes. In the five experienced subjects, transdiaphragmatic and pleural pressures, and electromyographs of the sternocleidomastoid and abdominal muscles were also measured. Subjects inspired against the resistor spontaneously and then with specific instructions to reach a target pleural or transdiaphragmatic pressure or to maximize selected electromyographic activities. Depending on the instructions, a wide variety of patterns of inspiratory motion resulted. Although the forces leading to a more elliptical or circular configuration of the chest wall can be identified, it is difficult to analyze or predict the configurational results based on insertional and pressure-related contributions of a few individual respiratory muscles. Although overall chest wall respiratory motion cannot be readily inferred from the electromyographic and pressure data we recorded, it is clear that responses to loading can vary substantially within and between individuals. Undoubtedly, the underlying mechanism for the distortional changes with loading are complex and perhaps many are behavioral rather than automatic and/or compensatory.     

Zone of apposition in the passive diaphragm of the dog

Boriek, Aladin M., Joseph R. Rodarte, and Susan S. Margulies. Zone of apposition in the passive diaphragm of thedog. J. Appl. Physiol. 81(5): 1929-1940, 1996.Wedetermined the regional area of the diaphragmatic zone of apposition(ZAP) as well as the regional craniocaudal extent of the ZAP(ZAP_ht) of the passive diaphragm in six paralyzedanesthetized beagle dogs (8-12 kg) at residual lung volume (RV),functional residual capacity (FRC), FRC + 0.25 and FRC + 0.5 inspiratory capacity, and total lung capacity (TLC) in prone and supinepostures. To identify the caudal boundary of the ZAP, 17 lead markers(1 mm) were sutured to the abdominal side of the costal and cruraldiaphragms around the diaphragm insertion on the chest wall. Two weekslater, the dogs' caudal thoraces were scanned by the use of thedynamic spatial reconstructor (DSR), a prototype fast volumetric X-raycomputer tomographic scanner, developed at the Mayo Clinic. Thethree-dimensional spatial coordinates of the markers were identified(±1.4 mm), and the cranial boundary of the ZAP was determined from30-40 1.4-mm-thick sagittal and coronal slices in each DSR image.We interpolated the DSR data to find the position of the cranial andcaudal boundaries of the ZAP every 5° around the thorax and computedthe distribution of regional variation of area of the ZAP andZAP_ht as well as the total area of ZAP. TheZAP_ht and area of ZAP increased as lung volume decreasedand were largest near the lateral extremes of the rib cage. We measuredthe surface area of the rib cage cephaled to the ZAP(A_L) in both postures in another six beagle dogs(12-16 kg) of similar stature, scanned previously in the DSR. Weestimated the entire rib cage surface area(A_rc = A_ZAP +A_L). The A_ZAP as a percentageof A_rc increased more than threefold as lung volumedecreased from TLC to RV, from ~9 to 29% of A_rc.