Relationship between heterogeneous changes in airway morphometry and lung resistance and elastance

Lutchen, Kenneth R., and Heather Gillis. Relationshipbetween heterogeneous changes in airway morphometry and lung resistanceand elastance. J. Appl. Physiol.83(4): 1192-1201, 1997.We present a dog lung model to predictthe relation between inhomogeneous changes in airway morphometry andlung resistance (RL) andelastance (EL) for frequenciessurrounding typical breathing rates. TheRL andEL were sensitive in distinctways to two forms of peripheral constriction. First, when there is alarge and homogeneous constriction, theRL increases uniformly over thefrequency range. The EL israther unaffected below 1 Hz but then increases with frequencies up to5 Hz. This increase is caused by central airway wallshunting. Second, the RL andEL are extremely sensitive to mild inhomogeneous constriction in which a few highly constricted ornearly closed airways occur randomly throughout theperiphery. This results in extreme increases in the levelsand frequency dependence of RLand EL but predominantly attypical breathing rates (<1 Hz). Conversely, theRL andEL are insensitive to highly inhomogeneous airway constriction that does not produce any nearly closed airways. Similarly, alterations in theRL andEL due to central airway wallshunting are not likely until the preponderance of the peripheryconstricts substantially. The RLand EL spectra are far moresensitive to these two forms of peripheral constriction than toconstriction conditions known to occur in the central airways. On thebasis of these simulations, we derived a set of qualitative criteria toinfer airway constriction conditions from RL andEL spectra.

     

Partitioning airway and lung tissue resistances in humans: effects of bronchoconstriction

Kaczka, David W., Edward P. Ingenito, Bela Suki, and KennethR. Lutchen. Partitioning airway and lung tissue resistances inhumans: effects of bronchoconstriction. J. Appl.Physiol. 82(5): 1531-1541, 1997.The contributionof airway resistance(Raw) and tissue resistance(Rti) to totallung resistance(RL)during breathing in humans is poorly understood. We have recentlydeveloped a method for separating Rawand Rti from measurements ofRLand lung elastance (EL)alone. In nine healthy, awake subjects, we applied a broad-band optimalventilator waveform (OVW) with energy between 0.156 and 8.1 Hz thatsimultaneously provides tidal ventilation. In four of the subjects,data were acquired before and during a methacholine (MCh)-bronchoconstricted challenge. TheRLandELdata were first analyzed by using a model with a homogeneous airwaycompartment leading to a viscoelastic tissue compartment consisting oftissue damping and elastance parameters. Our OVW-based estimates ofRaw correlated well with estimatesobtained by using standard plethysmography and were responsive toMCh-induced bronchoconstriction. Our data suggest thatRti comprises ~40% of totalRLat typical breathing frequencies, which corresponds to ~60% ofintrathoracic RL. During mildMCh-induced bronchoconstriction, Rawaccounts for most of the increase inRL. At high doses of MCh, therewas a substantial increase in RLat all frequencies and inEL athigher frequencies. Our analysis showed that bothRaw andRti increase, but most of the increaseis due to Raw. The data also suggestthat widespread peripheral constriction causes airway wall shunting toproduce additional frequency dependence inEL.

     

Airway-parenchymal interdependence after airway contraction in rat lung explants

The constrictionof pulmonary airways is limited by the tethering effect exerted byparenchymal attachments. To characterize this tethering effect at thescale of intraparenchymal airways, we studied the pattern ofparenchymal distortion due to bronchoconstriction in a rat lung explantsystem. First, we measured the elastic modulus under tension for 2%(wt/vol) agarose alone (37.6 ± 1.5 kPa) and for agarose-filled lung(5.7 ± 1.3 kPa). The latter is similar to the elastic modulus ofair-filled lung at total lung capacity (4.5-6 kPa) (S. J. Lai-Fook, T. A. Wilson, R. E. Hyatt, and J. R. Rodarte.J. Appl. Physiol. 40: 508-513,1976), suggesting that explants can be used as a model of lung tissuedistortion. Subsequently, confocal microscopic images of fluorescentlylabeled 0.5-mm-thick explants prepared from agarose-filled rat lungsinflated to total lung capacity (48 ml/kg) were acquired. Images weretaken before and after airway constriction was induced by directapplication of 10 mM methacholine, and the pattern of parenchymaldistortion was measured from the displacement of tissue landmarksidentified in each image for 14 explants. The magnitude of the radialcomponent of tissue displacement was calculated as a function ofdistance from the airway wall and characterized by a parameter,b, describing the rate at which tissuemovement decreased with radial distance. The parameterb was 0.994 ± 0.19 (SE), which isclose to the prediction of b = 1 ofmicromechanical modeling (T. A. Wilson. J. Appl.Physiol. 33: 472-478, 1972). There was significantvariability in b, however, which wascorrelated with the fractional reduction in airway diameter (r = 0.496). Additionally, parenchymaldistortion showed significant torsion with respect to the radialdirection. This torsion was similar in concentric zones around theairway, suggesting that it originates from inhomogeneity in theparenchyma rather than inhomogeneous airway constriction. Our resultsdemonstrate the significance of the nonlinear mechanical properties ofalveolar walls and the anisotropy of the parenchyma in determining the nature of airway-parenchymal interdependence.

     

Interaction between airway edema and lung inflation on responsiveness of individual airways in vivo

Brown, Robert H., Wayne Mitzner, and Elizabeth M. Wagner.Interaction between airway edema and lung inflation onresponsiveness of individual airways in vivo. J. Appl.Physiol. 83(2): 366-370, 1997.Inflammatorychanges and airway wall thickening are suggested to cause increasedairway responsiveness in patients with asthma. In fivesheep, the dose-response relationships of individual airways weremeasured at different lung volumes to methacholine (MCh) before andafter wall thickening caused by the inflammatory mediator bradykininvia the bronchial artery. At 4 cmH₂O transpulmonary pressure(Ptp), 5 µg/ml MCh constricted the airways to a maximum of 18 ± 3%. At 30 cmH₂O Ptp, MCh resultedin less constriction (to 31 ± 5%). Bradykinin increased airwaywall area at 4 and 30 cmH₂O Ptp(159 ± 6 and 152 ± 4%, respectively;P < 0.0001). At 4 cmH₂O Ptp, bradykinin decreasedairway luminal area (13 ± 2%; P < 0.01), and the dose-response curve was significantly lower (P = 0.02). At 30 cmH₂O, postbradykinin, the maximalairway narrowing was not significantly different (26 ± 5%;P = 0.76). Bradykinin produced substantial airway wall thickening and slight potentiation ofthe MCh-induced airway constriction at low lung volume. At high lung volume, bradykinin increased wall thickness but had no effecton the MCh-induced airway constriction. We conclude that inflammatoryfluid leakage in the airways cannot be a primary cause of airwayhyperresponsiveness.

     

Determination of airway and tissue resistances after antigen and methacholine in nonhuman primates

Madwed, Jeffrey B., and Andrew C. Jackson.Determination of airway and tissue resistances after antigen andmethacholine in nonhuman primates. J. Appl.Physiol. 83(5): 1690-1696, 1997.Antigen challenge of Ascaris suum-sensitiveanimals has been used as a model of asthma in humans. However, noreports have separated total respiratory resistance into airway (Raw)and tissue (Rti) components. We compared input impedance (Zin) andtransfer impedance (Ztr) to determine Raw and Rti in anesthetizedcynomolgus monkeys under control and bronchoconstricted conditions. Zindata between 1 and 64 Hz are frequency dependent during baselineconditions, and this frequency dependence shifts in response toA. suum or methacholine. Thus itcannot be modeled with the DuBois model, and estimates of Raw and Rticannot be determined. With Ztr, baseline data were much less variablethan Zin in all monkeys. After bronchial challenge withA. suum or methacholine, the absoluteamplitude of the resistive component of Ztr increased and its zerocrossing shifted to higher frequencies. These data can estimate Raw and Rti with the six-element DuBois model. Therefore, in monkeys, Ztr hasadvantages over other measures of lung function, since it provides amethodology to separate estimates of Raw and Rti. In conclusion, Ztrshows spectral features similar to those reported in healthy andasthmatic humans.

     

Effects of edema on small airway narrowing

Wagner, Elizabeth M. Effects of edema on small airwaynarrowing. J. Appl. Physiol. 83(3):784-791, 1997.Numerous mediators of inflammation have beendemonstrated to cause airway microvascular fluid and proteinextravasation. That fluid extravasation results in airway wall edemaleading to airway narrowing and enhanced reactivity has not beenconfirmed. In anesthetized, ventilated sheep(n = 30), airway vascularfluid extravasation was induced by infusing bradykinin(10⁶ M) through acannulated, blood-perfused bronchial artery. Airway wall edema andluminal narrowing were determined morphometrically. Airway reactivityto methacholine (MCh; 10 µg/ml, intrabronchial artery) was determinedby measuring conducting airway resistance (Raw) by forced oscillation.Raw measurements were made and lung lobes were excised and quick frozenbefore or after a 1-h bradykinin infusion. In 10 airways per lobe(range 0.2- to 2.0-mm relaxed diameter), wall area occupied 32 ± 2% (SE) of the total normalized airway area(n = 9). Bradykinin infusion increasedwall area to 42 ± 5% (P = 0.02);luminal area decreased by <5%; and smooth muscle perimeter, ameasure of smooth muscle constriction, was not altered(n = 5). Raw showed nochange from baseline (1.4 ± 0.4 cmH₂O · l¹ · s)after bradykinin infusion (n = 10).During MCh challenge, Raw increased by 3.2 ± 04 cmH₂O · l¹ · s,and this change did not differ after administration of bradykinin. MChchallenge caused similar decreases in smooth muscle perimeter (10%)and luminal area (72 vs. 68%) before and after bradykinin infusion.However, the time constant of recovery of Raw from MCh constriction wasincreased from control (40 ± 3 s) to 57 ± 10 s after bradykinininfusion (P = 0.03). When lung lobeswere excised at the same time after MCh challenge was terminated(n = 5), luminal area was greaterbefore bradykinin infusion than after (86 vs. 78%;P = 0.007), as was smooth muscleperimeter. The results of this study demonstrate that airway wall edemalimits relaxation after induced constriction rather than enhancingconstriction.

     

Importance of airway blood flow on particle clearance from the lung

Wagner, Elizabeth M., and W. Michael Foster. Importanceof airway blood flow on particle clearance from the lung.J. Appl. Physiol. 81(5):1878-1883, 1996.The role of the airway circulation insupporting mucociliary function has been essentially unstudied. Weevaluated the airway clearance of inert, insoluble particles inanesthetized ventilated sheep (n = 8),in which bronchial perfusion was controlled, to determine whetherairway mucosal blood flow is essential for maintaining surfacetransport of particles through airways. The bronchial branch of thebronchoesophageal artery was cannulated and perfused with autologousblood at control flow (0.6 ml ^· min^{1 ·} kg¹)or perfusion was stopped. With the sheep in a supine position and aftera steady-state ¹³³Xe ventilationscan for designation of lung zones of interest, an inert^99mTc-labeled sulfur colloidaerosol (2.1-µm diameter) was deposited in the lung. The clearancekinetics of the radiolabeled particles were determined from theactivity-time data obtained for right and left lung zones. At 60 minpostdeposition of aerosol, average airway particle retention forcontrol bronchial blood flow conditions was 57 ± 7 (SE)% for theright and 53 ± 8% for the left lung zones. Clearance of particleswas significantly impaired when bronchial blood flow was stopped, e.g.,right and left lung zones averaged 77 ± 6 and 76 ± 7% at 60 min, respectively (P < 0.05). Thesedata demonstrate a significant influence of the bronchial circulation on mucociliary transport of insoluble particles. Potential mechanisms that may account for these results include the importance of the bronchial circulation for nutrient flow, maintenance of airway walltemperature and humidity, and release of mediators and sequelae associated with tissue ischemia.

     

Partitioning of airway and respiratory tissue mechanical impedances by body plethysmography

Peslin, R., and C. Duvivier. Partitioning of airway andrespiratory tissue mechanical impedances by body plethysmography. J. Appl. Physiol. 84(2): 553-561, 1998.We have tested the feasibility of separating the airway (Zaw)and tissue (Zti) components of total respiratory input impedance(Zrs,in) in healthy subjects by measuring alveolar gas compression bybody plethysmography (Vpl) during pressure oscillations at the airwayopening. The forced oscillation setup was placed inside a bodyplethysmograph, and the subjects rebreathedBTPS gas. Zrs,in and the relationship between Vpl and airway flow (Hpl) were measured from 4 to 29 Hz. Zawand Zti were computed from Zrs,in and Hpl by using the monoalveolar T-network model and alveolar gas compliance derived from thoracic gasvolume. The data were in good agreement with previous observations: airway and tissue resistance exhibited some positive and negative frequency dependences, respectively; airway reactance was consistent with an inertance of 0.015 ± 0.003 hPa · s² · l¹and tissue reactance with an elastance of 36 ± 8 hPa/l. The changes seen with varying lung volume, during elastic loading of the chest andduring bronchoconstriction, were mostly in agreement with the expectedeffects. The data, as well as computer simulation, suggest that thepartitioning is unaffected by mechanical inhomogeneity and onlymoderately affected by airway wall shunting.

     

Greater airway narrowing in immature than in mature rabbits during methacholine challenge

Shen, X., V. Bhargava, G. R. Wodicka, C. M. Doerschuk, S. J. Gunst, and R. S. Tepper. Greater airway narrowing in immature thanin mature rabbits during methacholine challenge. J. Appl. Physiol. 81(6): 2637-2643, 1996.It hasbeen demonstrated that methacholine (MCh) challenge produces a greaterincrease in lung resistance in immature than in mature rabbits (R. S. Tepper, X. Shen, E. Bakan, and S. J. Gunst.J. Appl. Physiol. 79: 1190-1198, 1995). To determine whether this maturational difference in the response to MCh was primarily related to changes in airway resistance (Raw) or changes in tissue resistance, we assessed airway narrowing in1-, 2-, and 6-mo-old rabbits during intravenous MCh challenge (0.01-5.0 mg/kg). Airway narrowing was determined frommeasurements of Raw in vivo and from morphometric measurements on lungsections obtained after rapidly freezing the lung after the MChchallenge. The fold increase in Raw was significantly greater for 1- and 2-mo-old animals than for 6-mo-old animals. Similarly, the degree of airway narrowing assessed morphometrically was significantly greaterfor 1- and 2-mo-old animals than for 6-mo-old animals. The foldincrease in Raw was highly correlated with the degree of airwaynarrowing assessed morphometrically(r² = 0.82, P < 0.001). We conclude that thematurational difference in the effect of MCh on lung resistance isprimarily caused by greater airway narrowing in the immature rabbits.

     

Relationship between airway microvascular leakage, edema, and baseline airway functions

Matheson, Melissa, Ann-Christine Rynell, Melissa McClean,and Norbert Berend. Relationship between airway microvascular leakage, edema, and baseline airway functions. J. Appl. Physiol. 84(1): 77-81, 1998.This study wasdesigned to examine the relationship among microvascular leakage,edema, and baseline airway function. Microvascular leakage was inducedin the airways of anesthetized, tracheostomized New Zealand Whiterabbits (n = 22) by using nebulized N-formyl-methionyl-leucyl-phenylalanine(10 mg) and was measured in the trachea by using the Evans blue dyetechnique. Airway wall thickness was assessed morphometrically in theright main bronchus after Formalin fixation at a pressure of 25 cmH₂O. Areas calculated includedthe mucosal wall area, the adventitial wall area, the total wall area,and the percentage of total wall area consisting of blood vessels. Aneutrophil count was also performed by analyzing numbers of cells inboth the mucosal wall area and the adventitial wall area. Airwayfunction was assessed before and 30 min after challenge withN-formyl-methionyl-leucyl-phenylalanineby determining airway resistance, functional residual capacity,specific airway resistance, and flow-volume and pressure-volume curves(after paralysis of the animals with suxamethonium). The concentration of Evans blue dye in tracheal tissue ranged from 31.3 to 131.2 µg.There was a significant correlation between this concentration and boththe adventitial wall area (P < 0.01)and mucosal neutrophil numbers (P < 0.005). There was no correlation between Evans blue concentration andeither blood vessel area or changes in respiratory physiologyparameters before and after challenge. There was no significantdifference between any respiratory physiology measurements before andafter challenge. We conclude that an increase in microvascular leakagecorrelates with airway edema in the adventitia; however, these airwaychanges have no significant effect on airway elastic or resistiveproperties.

     

Lung tissue behavior in the mouse during constriction induced by methacholine and endothelin-1

Nagase, Takahide, Hirotoshi Matsui, Tomoko Aoki, YasuyoshiOuchi, and Yoshinosuke Fukuchi. Lung tissue behavior in the mouseduring constriction induced by methacholine and endothelin-1. J. Appl. Physiol. 81(6):2373-2378, 1996.Recently, mice have been extensively used toinvestigate the pathogenesis of pulmonary disease because appropriatemurine models, including transgenic mice, are being increasinglydeveloped. However, little information about the lung mechanics of miceis currently available. We questioned whether lung tissue behavior andthe coupling between dissipative and elastic processes, hysteresivity(), in mice would be different from those in the other species. Toaddress this question, we investigated whether tissue resistance (Rti)and  in mice would be affected by varying lung volume, constrictioninduced by methacholine (MCh) and endothelin-1 (ET-1), andhigh-lung-volume challenge during induced constriction. From measuredtracheal flow and tracheal and alveolar pressures in open-chest ICRmice during mechanical ventilation [tidal volume = 8 ml/kg,frequency (f) = 2.5 Hz], we calculated lung resistance(RL), Rti, airway resistance(Raw), lung elastance (EL),and  (=2fRti/EL). Underbaseline conditions, increasing levels of end-expiratory transpulmonarypressure decreased Raw and increased Rti. The administration ofaerosolized MCh and intravenous ET-1 increasedRL, Rti, Raw, andEL in a dose-dependent manner.Rti increased from 0.207 ± 0.010 to 0.570 ± 0.058 cmH₂O ^· ml^{1 ·} safter 10⁷ mol/kg ET-1(P < 0.01). After inducedconstriction, increasing end-expiratory transpulmonary pressuredecreased Raw. However,  was not affected by changing lung volume,constriction induced by MCh and ET-1, or high-lung-volume challengeduring induced constriction. These observations suggest that1)  is stable in mice regardlessof various conditions, 2) Rti is animportant fraction of RL andincreases after induced constriction, and3) mechanical interdependence mayaffect airway smooth muscle shortening in this species. In mammalianspecies, including mice, analysis of  may indicate that both Rti andEL essentially respond to asimilar degree.

     

Maturational changes in responses of tissue and airway resistance to histamine

Dreshaj, Ismail A., Musa A. Haxhiu, Charles F. Potter, FatonH. Agani, and Richard J. Martin. Maturational changes in responsesof tissue and airway resistance to histamine. J. Appl.Physiol. 81(4): 1785-1791, 1996.We determinedhow postnatal maturation affects the relative contributions of airwaysand lung parenchyma to pulmonary resistance(RL) and whether there are developmental differences in their respective responses to constrictive agents. We studied open-chest ventilated anesthetized piglets of threeages: 2-4 days, 2-3 wk, and 10 wk.RL was partitioned into tissue(Rti) and airway (Raw) resistance by means of alveolar capsules underbaseline conditions and after intravenous histamine. Postnatalmaturation was associated with a progressive decline inRL, Rti, and Raw and with anincrease in the contribution of Rti toRL from 38 ± 8% at 2-4days to 72 ± 2% at both 2-3 and 10 wk. Histamine causedRL to increase at all ages. Whenpartitioned into Rti and Raw, the percent increase in Rti significantlyexceeded that of Raw at both 2-4 days and 2-3 wk. Incontrast, the percent increase in Raw significantly exceeded that ofRti at 10 wk. Administration of atropine before histamine in pigletsaged 10 wk reduced the response of Rti and Raw to histamine.Histamine-induced responses ofRL were blocked by priorH₁-receptor blockade withpyrilamine (2 mg/kg). These results indicate that1) the contribution of Rti and Rawto RL changes during maturationand that 2) contractile responses toexogenous histamine are manifest predominantly in most distal airwaysand lung parenchyma during early postnatal life; with advancingmaturation there is greater contribution of airways to the increase inRL induced by histamine.

     

Inhibition of allergic airway responses by inhaled low-molecular-weight heparins: molecular-weight dependence

Martinez-Salas, José, Richard Mendelssohn, William M. Abraham, Bernard Hsiao, and Tahir Ahmed. Inhibition of allergic airway responses by inhaled low-molecular-weight heparins:molecular-weight dependence. J. Appl.Physiol. 84(1): 222-228, 1998.Inhaled heparin prevents antigen-induced bronchoconstriction and inhibitsanti-immunoglobulin E-mediated mast cell degranulation. We hypothesizedthat the antiallergic action of heparin may be molecular weightdependent. Therefore, we studied the effects of three differentlow-molecular-weight fractions of heparin [medium-, low-, andultralow-molecular-weight heparin (MMWH, LMWH, ULMWH,respectively)] on the antigen-induced acute bronchoconstrictorresponse (ABR) and airway hyperresponsiveness (AHR) in allergic sheep.Specific lung resistance was measured in 22 sheep before and afterairway challenge with Ascarissuum antigen, without and afterpretreatment with inhaled fractionated heparins at doses of0.31-5.0 mg/kg. Airway responsiveness was estimated before and 2 hpostantigen as the cumulative provocating dose of carbachol in breathunits that increased specific lung resistance by 400%. Allfractionated heparins caused a dose-dependent inhibition of ABR andAHR. ULMWH was the most effective fraction, with the inhibitory dosecausing 50% protection (ID₅₀)against ABR of 0.5 mg/kg, whereasID₅₀ values of LMWH and MMWH were1.25 and 1.8 mg/kg, respectively. ULMWH was also the most effective fraction in attenuating AHR; theID₅₀ values for ULMWH, LMWH, andMMWH were 0.5, 2.5, and 4.7 mg/kg, respectively. These data suggestthat 1) fractionatedlow-molecular-weight heparins attenuate antigen-induced ABR and AHR;2) there is an inverse relationship between the antiallergic activity of heparin fractions and molecular weight; and 3) ULMWH is the mosteffective fraction preventing allergic bronchoconstriction and airwayhyperresponsiveness.

     

A distributed nonlinear model of lung tissue elasticity

Maksym, Geoffrey N., and Jason H. T. Bates. Adistributed nonlinear model of lung tissue elasticity.J. Appl. Physiol. 82(1): 32-41, 1997.- We present a theory relating the static stress-strainproperties of lung tissue strips to the stress-bearing constituents,collagen and elastin. The fiber pair is modeled as a Hookean spring(elastin) in parallel with a nonlinear string element (collagen), whichextends to a maximum stop length. Based on a series of fiber pairs, wedevelop both analytical and numerical models with distributedconstituent properties that account for nonlinear tissue elasticity.The models were fit to measured stretched stress-strain curves of fiveuniaxially stretched tissue strips, each from a different dog lung. Wefound that the distributions of stop length and spring stiffness followinverse power laws, and we hypothesize that this results from thecomplex fractal-like structure of the constituent fiber matrices inlung tissue. We applied the models to representative pressure-volume(PV) curves from patients with normal, emphysematous,and fibrotic lungs. The PV curves were fit to theequation V = A  Bexp(KP),where V is volume, P is transpulmonary pressure, andA, B, andK are constants. Our models lead to apossible mechanistic explanation of the shape factorK in terms of the structuralorganization of collagen and elastin fibers.

     

Lung parenchymal shear modulus, airway wall remodeling, and bronchial hyperresponsiveness

Lambert, Rodney K., and Peter D. Paré. Lungparenchymal shear modulus, airway wall remodeling, and bronchialhyperresponsiveness. J. Appl. Physiol.83(1): 140-147, 1997.When airways narrow, either through theaction of smooth muscle shortening or during forced expiration, thelung parenchyma is locally distorted and provides an increasedperibronchial stress that resists the narrowing. Although thisinterdependence has been well studied, the quantitative significance ofairway remodeling to interdependence has not been elucidated. We haveused an improved computational model of the bronchial response tosmooth muscle agonists to investigate the relationships between airwaynarrowing (as indicated by airway resistance), parenchymal shearmodulus, adventitial thickening, and inner wall thickening at lungrecoil pressures of 4, 5, and 8 cmH₂O. We have found that, at lowrecoil pressures, decreases in parenchymal shear modulus have asignificant effect that is comparable to that of moderate thickening ofthe airway wall. At higher lung recoil pressures, the effect isnegligible.

     

Strain-induced growth of the immature lung

Zhang, Shaoping, Vicki Garbutt, and John T. McBride.Strain-induced growth of the immature lung. J. Appl. Physiol. 81(4): 1471-1476, 1996.Toinvestigate the relationship between strain and postnatal lung growth,two groups of weanling ferrets were tracheotomized: the study group wasexposed for 2 wk to a continuous positive airway pressure (CPAP) of 6 cmH₂O and the other group wasexposed to atmospheric pressure (control). Total lung capacity after 2 wk was ~40% higher in the CPAP-exposed animals than in the controlanimals (n = 19 for the control groupand 18 for the study group; P < 0.01). CPAP exposure was also associated with increases in lung weightand total lung protein and DNA contents. Lung recoil, measured in asubgroup of animals, was characterized by air-filled and saline-filledstatic expiratory pressure-volume curves. Neither in the air-filledlungs nor in the saline-filled lungs was there a significant differencebetween CPAP-exposed and control animals in lung recoil at equalfractions of total lung capacity. These data indicate that mechanicalstrain was associated with an acceleration of lung growth in immatureferrets. The preservation of volume-corrected lung recoil and theexpected contribution of surface forces and tissue forces to lungrecoil in CPAP-exposed animals suggest that this response did notinvolve simple lung distension but included a remodeling of the lungparenchyma.

     

Effect of tidal volume and frequency on airway responsiveness in mechanically ventilated rabbits

Shen, X., S. J. Gunst, and R. S. Tepper. Effect oftidal volume and frequency on airway responsiveness in mechanically ventilated rabbits. J. Appl. Physiol.83(4): 1202-1208, 1997.We evaluated the effects of the rate andvolume of tidal ventilation on airway resistance (Raw) duringintravenous methacholine (MCh) challenge in mechanically ventilatedrabbits. Five rabbits were challenged at tidal volumes of 5, 10, and 20 ml/kg at a frequency of 15 breaths/min and also under static conditions(0 ml/kg tidal volume). Four rabbits were subjected to MCh challenge atfrequencies of 6 and 30 breaths/min with a tidal volume of 10 ml/kg andalso under static conditions. In both groups, the increase in Raw with MCh challenge was significantly greater under static conditions thanduring tidal ventilation at any frequency or volume. Increases in thevolume or frequency of tidal ventilation resulted in significant decreases in Raw in response to MCh. We conclude that tidal breathing suppresses airway responsiveness in rabbits in vivo. The suppression ofnarrowing in response to MCh increases as the magnitude of the volumeor the frequency of the tidal oscillations is increased. Our findingssuggest that the effect of lung volume changes on airway responsivenessin vivo is primarily related to the stretch of airway smooth muscle.

     

Long-term facilitation of upper airway muscle activities in vagotomized and vagally intact cats

Mateika, J. H., and R. F. Fregosi. Long-termfacilitation of upper airway muscle activities in vagotomized andvagally intact cats. J. Appl. Physiol.82(2): 419-425, 1997.The primary purpose of the presentinvestigation was to determine whether long-term facilitation (LTF) ofupper airway muscle activities occurs in vagotomized and vagally intactcats. Tidal volume and diaphragm, genioglossus, and nasal dilatormuscle activities were recorded before, during, and after one carotidsinus nerve was stimulated five times with 2-min trains of constantcurrent. Sixty minutes after stimulation, nasal dilator andgenioglossus muscle activities were significantly greater than controlin the vagotomized cats but not in the vagally intact cats. Tidalvolume recorded from the vagotomized and vagally intact cats wassignificantly greater than control during the poststimulation period.In contrast, diaphragm activities were not significantly elevated inthe poststimulation period in either group of animals. We conclude that1) LTF of genioglossus and nasaldilator muscle activities can be evoked in vagotomized cats;2) vagal mechanisms inhibit LTF inupper airway muscles; and 3) LTF canbe evoked in accessory inspiratory muscles because LTF of inspiredtidal volume was greater than LTF of diaphragm activity.

     

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.

     

Nitric oxide derived from sympathetic nerves regulates airway responsiveness to histamine in guinea pigs

Matsumoto, Koichiro, Hisamichi Aizawa, Shohei Takata,Hiromasa Inoue, Naotsugu Takahashi, and Nobuyuki Hara.Nitric oxide derived from sympathetic nerves regulates airwayresponsiveness to histamine in guinea pigs. J. Appl.Physiol. 83(5): 1432-1437, 1997.Nitric oxide(NO), which can be derived from the nervous system or the epithelium ofthe airway, may modulate airway responsiveness. We investigated how NOderived from the airway nervous system would affect the airwayresponsiveness to histamine and acetylcholine in mechanicallyventilated guinea pigs. An NO synthase inhibitor N^G-nitro-L-argininemethyl ester (L-NAME) (1 mmol/kgip) significantly enhanced airway responsiveness to histamine but notto acetylcholine. Its enantiomerD-NAME (1 mmol/kg ip), incontrast, had no effect. TheL-NAME-induced airwayhyperresponsiveness was still observed in animals pretreated withpropranolol (1 mg/kg iv) and atropine (1 mg/kg iv). Pretreatment withthe ganglionic blocker hexamethonium (2 mg/kg iv) completely abolishedenhancing effect of L-NAME on airway responsiveness. Bilateral cervical vagotomy did not alter theL-NAME-induced airwayhyperresponsiveness, whereas sympathetic stellatectomy completelyabolished it. Results suggest that NO that was presumably derived fromthe sympathetic nervous system regulates airway responsiveness tohistamine in guinea pigs.