Interpreting Penh in mice

doi:10.1152/japplphysiol.00815.2002

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Interpreting Penh in mice

The following is the abstract of the article discussed in the subsequent letter:

	ABSTRACT

Lundblad, Lennart K. A., Charles G. Irvin, Andy Adler, and Jason H. T. Bates. A reevaluation of the validity of unrestrainedplethysmography in mice. J Appl Physiol 93: 1198-1207, 2002. $---$ Presently,unrestrained plethysmography is widely used to assess bronchialresponsiveness in mice. An empirical quantity known as enhancedpause is derived from the plethysmographic box pressure [P_b(t),where t is time] and assumed to be an index of bronchoconstriction.We show that P_b(t) is determined largely by gas conditioning whennormal mice breathe spontaneously inside a closed chamber in whichthe air is at ambient conditions. When the air in the chamberis heated and humidified to body conditions, the changes in P_b(t)are reduced by about two-thirds. The remaining changes are thusdue to gas compression and expansion within the lung and are amplifiedwhen the animals breathe through increased resistances. We showthat the time integral of P_b(t) over inspiration is accuratelypredicted by a term containing airway resistance, functional residualcapacity, and tidal volume. We conclude that unrestrained plethysmographycan be used to accurately characterize changes in airway resistanceonly if functional residual capacity and tidal volume are measuredindependently and the chamber gas is preconditioned to body temperatureandhumidity.

	INTERPRETING PENH IN MICE

To the Editor: In the October 2002 issue of the Journal of Applied Physiology, Lundblad et al. (18) described experimentalwork that concluded with criticism of the use of the enhancedpause (Penh) variable to estimate airway resistance. In the sameissue, an editorial by Hantos and Brusasco (16) supported thiscriticism. Although we also agree that Penh is not a very reliablerespiratory variable, we feel that the criticisms leveled againstit in these two articles were perhaps a bit too polite. In fact,there are several concerns with the work by Lundblad et al. thatled the authors to overestimate considerably even the small importanceof Penh that they found. In the discussion below, we very brieflyreview some salient points that bear directly on thisissue.

Part of the dilemma over what Penh actually measures arises from the well-accepted use of the same plethysmograph pressureto measure tidal volume (7, 19, 23). Tidal volume measurementsmade with this method in the mouse provide values that are consistentwith more direct measurements and mammalian scaling (23). Sucha volume measurement, however, appears to be in contrast to themeasurement of airway resistance in humans, as originally describedby Dubois et al. (8). This classic method involves placinga human in a closed box and using the recorded box pressure toquantify airway resistance. However, procedures that use thisapproach in humans, that is, breathing at very high frequenciesand very low tidal volumes, have been carefully designed to maximizethe resistive component of the pressure while minimizing the tidalvolume component. Because this method requires voluntary modificationsof breathing, it obviously cannot be done in any experimentalanimal. As we will show, the extent to which this minimizationoccurs in a mouse breathing normally is in factnegligible.

	SIMPLE THEORETICAL CONSIDERATIONS

Although Lundblad et al. (18) described the theoretical basis of the pressure in the plethysmograph, we need to brieflyrestate these considerations here in even simpler terms. The setupis to place a mouse inside of a box. During inspiration it isobserved that the box pressure rises, and during expiration thebox pressure falls. The rise in pressure during inspiration canoccur for two very different reasons. The first is that tidalair, as it moves from the box into the lungs, is warmed to corebody temperature (37°C) and humidified to 100% relative humidityby the time gas reaches the alveolar spaces. These effects resultin an increase in water vapor pressure and a thermal expansionof gas, both of which increase pressure in the plethysmographbox. The larger the tidal volume, the larger the pressure increase,with other factors beingequal.

The second reason for an inspiratory increase in box pressure is a decompression of alveolar gas. This effect is easily appreciatedif an inspiratory effort is made against a closed glottis or upperairway. The gas in the lung will expand in proportion to the fallin alveolar pressure with the inspiratory effort and the magnitudeof lung volume. If we now allow inspiration to occur during theinspiratory effort, there will still be some decompression ofthe alveolar gas, now in proportion to the inspiratory flow rateand resistance of theairways.

In the following sections, we present calculations to estimate the relative magnitudes of each of these inspiratory pressurecomponents for a quietly breathing mouse in a sealed 300-ml plethysmograph.Regarding these simplified calculations, two points are worthnoting. First, the size of the plethysmograph is not criticalbecause both pressure components vary inversely with the box size.Thus comparison of the relative magnitudes will be unaffected.Second, when dealing with an animal in a body box, there is oneimportant concern that is nearly always ignored: the pressureson inspiration and expiration are not symmetrical. That is, withambient temperature less than body temperature, the pressure riseon inspiration is always greater than the fall on expiration.Two reasons are responsible for this observation: the first isthat the box temperature slowly rises because of the animal'spresence, and the second is that the drying and cooling of theexpired air in the nasal passages cause less of a pressure dropon exhalation. This latter effect was elegantly analyzed by Epsteinand Epstein (10); however, because it is not easy to measurethe water vapor pressure or temperature of exhaled air in mostspecies, especially the mouse, the corrections they derived havenot been utilized. We do not know precisely how much this effectapplies in the mouse; however, on the basis of their equationsand nominal values, the pressure fall on expiration might be asmuch as 30-50% smaller than that on inspiration. To avoid worryingabout this unpleasant effect and drift in the box pressure, nearlyall investigators simply ignore the problem by putting a smallhole in the box, thereby creating a high-resistance leak to "stabilize"the pressure trace. It is also worth noting here that the effectof alveolar gas compression on expiratory box pressure will alsobe smaller than that on inspiration because the peak expiratoryflow is normally less than peak inspiratory flow. Our generalquantitative conclusions, therefore, would not be greatly changedif we had enough information to do the more detailed calculationonexpiration.

Tidal volume expansion. On the basis of the original analysis in the 1955 paper of Drorbaugh and Fenn (7), the following formula can be used forthe pressure increase during inspiration

&Dgr;Pbox =

V<SC>t</SC>/Cgas[1 − (Tbox/Tlung)(P<SC>b − Ph</SC><SUB>2</SUB><SC>o</SC>,lung)/(P<SC>b</SC> − P<SC>h</SC><SUB>2</SUB><SC>o</SC>,box)]

where VT is tidal volume, Tbox and Tlung are temperature (°K) in box and lung, respectively, PB is barometric pressure, PH₂O,boxand PH₂O,lung are water vapor pressure in box and lung, respectively,and Cgas is compliance (mostly adiabatic compressibility) of theair in the plethysmograph (~75 ml · cmH₂O¹ · l¹).

For nominal calculations, we need to make certain reasonable assumptions regarding these variables. We assume PB = 760 Torr,PH₂O,lung = 47 Torr, Tlung = 310°K, Tbox = 297°K, PH₂O,box = 10Torr, and VT = 0.2 ml. Cgas is equal to 0.23 ml/cmH₂O.

With these values, the inspiratory rise in box pressure is ~0.08 cmH₂O.

Alveolar decompression. The increase in Pbox during inspiration from alveolar decompression is given by the following simple equation based on Boyle'slaw

&Dgr;Pbox = −&Dgr;P<SC>a</SC> (V<SC>l</SC>/Vbox)

where $Delta$ PA is the maximal decrease in alveolar pressure, VL is lung volume at end inspiration, and Vbox = 300ml.

For nominal calculations, we need to estimate a value for the maximal decrease in alveolar pressure. This depends on the inspiratoryflow and airway resistance with quiet breathing. With a tidalvolume of 0.2 ml, a frequency of 2 Hz, and an inspiratory-to-expiratoryratio of 1:2, the peak inspiratory flow is ~2 ml/s. With a mouseairway resistance of 1.7 cmH₂O · ml¹ · s (11), the maximal fall in alveolar pressure will be <3.4cmH₂O.

With these values, and a nominal mouse end-inspiratory volume of 0.5 ml (functional residual capacity of 0.3 ml + tidal volumeof 0.2 ml) (20), the inspiratory rise in box pressure is 0.006cmH₂O.

	DISCUSSION

These simple theoretical calculations, using physical chemical laws and nominal widely accepted values for mouse lung function,show that, at baseline, the pressure component resulting fromairway resistance is at least an order of magnitude smaller thanthat from expansion of the tidal volume. We say at least an orderof magnitude smaller because, by using an estimate of airway resistancefrom our own laboratory that is almost double what several otherlaboratories have found after correcting for tissue resistance(22, 24), we may have substantially overestimated the magnitudeof the decompression component. Indeed, this conclusion is supportedby the results of a clever study done by Enhorning et al. (9).They set up a mechanical bellows, connected inside the box withan equivalent airway resistance, that could be oscillated in amouse plethysmograph at various breathing frequencies and volumes;they compared these pressure excursions with those from a livemouse. Although the conclusions reached by these investigatorswere that the pressure increments from tidal volume and decompressionwere about equal, the mechanical lung had a volume that was muchgreater than that of a mouse lung. The bellows that they usedto simulate the lung had a volume of 6 ml, or at least 12 timesa mouse end-inspiratory volume. Because the magnitude of the decompressioncomponent of box pressure is directly proportional to the ratioof lung to box volume, this increased mechanical "lung" volumethus led them to overestimate the contribution of the decompressionpressure by an order of magnitude. This recalculation thus makestheir experimental results quite consistent with our conclusionbased on the simple equationsabove.

From our simple theoretical considerations above and the experiments of Enhorning et al. (9), the original question remainsas to why Lundblad et al. (18) concluded that the decompressioncomponent was one-third of the total box pressure. They basedthis conclusion on the results of their experiments in which thetemperature in the body box was raised to 37°C in an effort tocompletely eliminate the pressure component resulting from tidalvolume expansion. There are several reasons why this experimentwould have substantially overestimated the box pressure componentthat resulted from airway resistance. First, they made no measurementof the animals' body temperatures. When the box temperature israised to 37°C, it is very likely that the animal's core bodytemperature rises above this value. Second, they did not measureor control the box relative humidity. When the ambient temperatureis heated, the relative humidity will fall. Both of these effects,however small, will maintain some finite fraction of the tidalvolume pressure component. In addition, because the tidal volumepressure component starts at about 10 times greater, one doesnot need much of this component to have a very big effect. Evena 97% reduction of the magnitude of this tidal pressure componentwould still result in it being at the level found by Lundbladet al. (i.e., ~30% of the decompression component). A third reasonthat may have led to an overestimation of this decompression componentrelates to the calculated external resistance required by theexperimental preparation, including the tracheotomy tube and connectingtubing. As was noted some years ago by Chang and Mortola (3),the resistance of a tube in the trachea may be considerably higherthan that measured outside. The magnitude of this factor in themouse airway is not certain, but it could have led to an increasedresistive component in thecalculations.

As emphasized by Hantos and Brusasco (16), measurement of airway responsiveness in mice adds a critical functional componentto many studies that involve genetic and chemical manipulations.In an early study of the genetic variation in mouse airway responsiveness,mice were anesthetized and mechanically ventilated to assess theresponse of airway smooth muscle to acetylcholine (17). Thisprocedure, as well as others that directly measured lung resistance(2, 5, 13, 22, 25), required killing that animal afterthe measurement. This necessity limited the usefulness in long-termstudies, especially if one had required measurements at many timepoints. Although it is possible to intubate mice and measure airwaysmooth muscle responsiveness without causing death (1), thisstill requires animals to be anesthetized. Thus the research communityshowed great interest in the 1998 paper by Hamelmann et al. (15),which described the use of a commercial plethysmograph that hadthe promise of being able to assess responses of airways noninvasivelyin conscious animals. The dimensionless parameter, Penh, was definedfrom the box pressure waveform, and a correlation with the othermore direct indexes of airway responsiveness was found in theirexperiments. After publication of this article, we sent a briefletter to the journal questioning how it was possible that thesame pressure that had been used successfully for many years inmany species to measure tidal volume could now be used to measureairway resistance (21). It seemed to be the ultimate dream variablefor physiologists, one that could be used to extract informationon whatever one wanted to know. Despite this early concern withthe use of Penh, many investigators studying lung function inmice have been seduced by its noninvasive simplicity and havechosen to rely on this method (4, 6, 12, 14, 26).

The results presented here clearly show that, with a mouse undergoing baseline quiet breathing, the pressure in the body plethysmographthat results from the size of the airways is trivial. This isan important result that impacts on the interpretation of studiesthat use indexes such as Penh to assess changes in airway responsiveness.In most such studies, changes are assessed by normalization tothe baseline Penh. It makes no scientific sense, however, to comparesuch changes with a baseline variable that has nothing to do withairway size. This is true even if there is a large increase inthe decompression component. With a large increase in airway resistance,the fraction of box pressure that arises from the resistance willof course increase, and this might be detectable, assuming thatthere were no other changes in tidal volume or breathing pattern.This assumption, however, is not supported by observation, soeven the ability to quantify the absolute effect is scientificallysuspect.

One additional concern with the paper by Lundblad et al. (18) is that the investigators never actually measured Penh intheir experimental animals. Although their theoretical calculationssupport the results presented here, that box pressure containsessentially no information about airway size, it would have beenhelpful to see how Penh changed as the box temperature was raised.Perhaps one reason they avoided this calculation is that the methodto calculate it has never been clearly defined. Published worksthat use Penh cite the Hamelmann et al. paper (15), but, aswe also noted previously (21), their description of the calculationis inadequate. As we have described above and also as clearlyshown by Lundblad et al. (18), box pressure rises during inspirationand falls during expiration. Figure 2 in Hamelmann et al., whichis used to describe the Penh calculation, does not show this.And furthermore, because most box pressure traces from a consciousanimal in the box show rapid up-and-down oscillating pressure,such as that shown in Fig. 3a of Hamelmann et al., there is noobvious way to apply the analysis in their Fig. 2 to make a Penhcalculation from such a trace. Perhaps Lundblad et al. also feltit impossible to make such calculations, but this was notdiscussed.

Finally, it is worth noting that, given the demand for rapid screening of mouse pulmonary function, the situation of usingPenh to assess mouse pulmonary function has almost reached epidemicdependency. After a presentation critical of the use of Penh byone of us (Mitzner) at a minisymposium on lung mechanics in themouse at the 2002 American Thoracic Society meeting, someone askedthe following: if indeed Penh was not a useful measurement ofairway responsiveness, what could be used instead? The companyfor which the questioner worked required measurements of airwayresponsivity in mice, and the questioner almost demanded us toprovide an alternative. It appears that current desires and needsto have some easy, unthinking way to assess mouse lung functionhave created a Penh addiction in many investigators. Unfortunately,we regret to report that, at the present time, there is no physiologicalmethadone to treat thisaddiction.

Perhaps one thing investigators might do to maintain some perspective is not to use the term Penh. Giving this nonsense variablea unique name that resembles a pressure makes it too easy to misinterpretquantitative changes that, in fact, have no relation to the sizeof the airways. An observed doubling of Penh has no more informationabout the airways than a tripling of Penh because, as noted, thebaseline measurement contains essentially no information contentabout airways. If investigators cannot control their need to measurethis, we would suggest calling it ventilatory timing (e.g., likeexpiratory time) or simply ventilation. Then at least one maybe less likely to misinterpret experimental results. Observationsof increased "ventilatory timing" after some intervention or challengemight then lead one to attempt to make meaningful quantitativemeasurements that relate to airway size. Of course, this approachwill still totally miss those situations in which airways areaffected with minimal ventilatory effects, but this may be theprice one pays foraddiction.

	REFERENCES

1. Brown, RH, Walters DM, Greenberg RS, and Mitzner W. A method of endotracheal intubation and pulmonary functional assessment for repeated studies in mice. J Appl Physiol 87: 2362-2365, 1999[Abstract/Free Full Text].

2. Bulut, Y, Kleeberger SR, and Hirshman CA. Cholinesterase activity is similar in C3H/HeJ and A/J mice and does not account for their different bronchoconstrictor responsiveness. Exp Lung Res 25: 367-378, 1999[ISI][Medline].

3. Chang, HK, and Mortola JP. Fluid dynamic factors in tracheal pressure measurement. J Appl Physiol 51: 218-225, 1981[Abstract/Free Full Text].

4. Dakhama, A, Kanehiro A, Makela MJ, Loader JE, Larsen GL, and Gelfand EW. Regulation of airway hyperresponsiveness by calcitonin gene-related peptide in allergen sensitized and challenged mice. Am J Respir Crit Care Med 165: 1137-1144, 2002[Abstract/Free Full Text].

5. De Sanctis, GT, Wolyniec WW, Green FH, Qin S, Jiao A, Finn PW, Noonan T, Joetham AA, Gelfand E, Doerschuk CM, and Drazen JM. Reduction of allergic airway responses in P-selectin-deficient mice. J Appl Physiol 83: 681-687, 1997[Abstract/Free Full Text].

6. Dohi, M, Tsukamoto S, Nagahori T, Shinagawa K, Saitoh K, Tanaka Y, Kobayashi S, Tanaka R, To Y, and Yamamoto K. Noninvasive system for evaluating the allergen-specific airway response in a murine model of asthma. Lab Invest 79: 1559-1571, 1999[ISI][Medline].

7. Drorbaugh, JE, and Fenn WO. A barometric method for measuring ventilation in newborn infants. Pediatrics 16: 81-87, 1955[Abstract/Free Full Text].

8. Dubois, AB, Botelho SY, and Comroe JH. A new method for measuring airway resistance in man using a body plethysmograph. J Clin Invest 35: 327-335, 1956[ISI][Medline].

9. Enhorning, G, van Schaik S, Lundgren C, and Vargas I. Whole-body plethysmography, does it measure tidal volume of small animals? Can J Physiol Pharmacol 76: 945-951, 1998[ISI][Medline].

10. Epstein, MA, and Epstein RA. A theoretical analysis of the barometric method for measurement of tidal volume. Respir Physiol 32: 105-120, 1978[ISI][Medline].

11. Ewart, SL, Levitt RC, and Mitzner W. Respiratory system mechanics in mice measured by end-inflation occlusion. J Appl Physiol 79: 560-566, 1995[Abstract/Free Full Text].

12. Goldsmith, CA, Ning Y, Qin G, Imrich A, Lawrence J, Murthy GG, Catalano PJ, and Kobzik L. Combined air pollution particle and ozone exposure increases airway responsiveness in mice. Inhal Toxicol 14: 325-347, 2002[ISI][Medline].

13. Gomes, RF, Shen X, Ramchandani R, Tepper RS, and Bates JH. Comparative respiratory system mechanics in rodents. J Appl Physiol 89: 908-916, 2000[Abstract/Free Full Text].

14. Hamada, K, Goldsmith CA, Goldman A, and Kobzik L. Resistance of very young mice to inhaled allergen sensitization is overcome by coexposure to an air-pollutant aerosol. Am J Respir Crit Care Med 161: 1285-1293, 2000[Abstract/Free Full Text].

15. Hamelmann, E, Schwarze J, Takeda K, Oshiba A, Larsen GL, Irvin CG, and Gelfand EW. Noninvasive measurement of airway responsiveness in allergic mice using barometric plethysmography. Am J Respir Crit Care Med 156: 766-775, 1997[Abstract/Free Full Text].

16. Hantos, Z, and Brusasco V. Assessment of respiratory mechanics in small animals: the simpler the better? J Appl Physiol 93: 1196-1197, 2002[Free Full Text].

17. Levitt, RC, and Mitzner W. Expression of airway hyperreactivity to acetylcholine as a simple autosomal recessive trait in mice. FASEB J 2: 2605-2608, 1988[Abstract].

18. Lundblad, LKA, Irvin CG, Adler A, and Bates JHT A reevaluation of the validity of unrestrained plethysmography in mice. J Appl Physiol 93: 1198-1207, 2002[Abstract/Free Full Text].

19. Malan, A. Ventilation measured by body plethysmography in hibernating mammals and in poikilotherms. Respir Physiol 17: 32-44, 1973[ISI][Medline].

20. Mitzner, W, Brown R, and Lee W. In vivo measurement of lung volumes in mice. Physiol Genomics 4: 215-221, 2001[Abstract/Free Full Text].

21. Mitzner, W, and Tankersley C. Noninvasive measurement of airway responsiveness in allergic mice using barometric plethysmography. Am J Respir Crit Care Med 158: 340-341, 1998[ISI].

22. Petak, F, Habre W, Donati YR, Hantos Z, and Barazzone-Argiroffo C. Hyperoxia-induced changes in mouse lung mechanics: forced oscillations vs. barometric plethysmography. J Appl Physiol 90: 2221-2230, 2001[Abstract/Free Full Text].

23. Tankersley, CG, Fitzgerald RS, Levitt RC, Mitzner W, Ewart SL, and Kleeberger SR. Genetic control of differential baseline breathing pattern. J Appl Physiol 82: 874-881, 1997[Abstract/Free Full Text].

24. Tomioka, S, Bates JH, and Irvin CG. Airway and tissue mechanics in a murine model of asthma: alveolar capsule vs. forced oscillations. J Appl Physiol 93: 263-270, 2002[Abstract/Free Full Text].

25. Wills-Karp, M, Luyimbazi J, Xu X, Schofield B, Neben TY, Karp CL, and Donaldson DD. Interleukin-13: central mediator of allergic asthma. Science 282: 2258-2261, 1998[Abstract/Free Full Text].

26. Zeldin, DC, Wohlford-Lenane C, Chulada P, Bradbury JA, Scarborough PE, Roggli V, Langenbach R, and Schwartz DA. Airway inflammation and responsiveness in prostaglandin H synthase-deficient mice exposed to bacterial lipopolysaccharide. Am J Respir Cell Mol Biol 25: 457-465, 2001[Abstract/Free Full Text].

Wayne Mitzner,
Clarke Tankersley
Department of Physiology
Johns Hopkins University
Baltimore, Maryland 21205
E-mail: wmitzner{at}jhsph.edu

To the Editor: The purpose of our study (1) was to experimentally demonstrate the physical processes involved in producingthe box pressure swings provided by unrestrained plethysmography.Our key result was to show that most of these pressure swingsobtained with an unconstricted animal are due to gas conditioning,which has nothing to do with factors that determine lung mechanics.There is, however, a component of the box pressure swing thatdoes reflect thoracic gas compression, which may be affected bychanges in lung mechanics. Mitzner and Tankersley provide a ratherconvincing argument that we may have overestimated the pressureswings due to gas compression in the thorax. The pressure swingswe measured in our study, after heating and humidifying the gasin the box, were small and not easily resolved above the cardiogenicoscillations. We therefore concede that Mitzner and Tankersleymay well be correct in their assertion that the box pressure variationsdue to gas compression are significantly less than we indicated,to the point of being essentially negligible under baseline conditions,although it is important to point out that their results are theoretical,whereas we have provided direct measurements (and we did measurerelative humidity in the box, contrary to the assertion by Mitznerand Tankersley that we did not). We also endorse their excellentpoint that it makes no sense to normalize values of enhanced pause(Penh) during bronchoconstriction (when gas compression may besignificant) to baseline values that are independent of gas compressionand therefore of lungmechanics.

From a practical point of view, it hardly matters whether our baseline measurements of gas compression or those estimatedby Mitzner and Tankersley are more correct because Penh as a measureof lung mechanical function is clearly shown to be highly suspectin either case. Thus we and Mitzner and Tankersley are of likemind in thinking that Penh has little utility as it is currentlyemployed. Also in agreement with Mitzner and Tankersley, we havethe impression that the current widespread fascination with Penhis born of wishful thinking and an inability to accept the unfortunatefact that, for the moment, there is no way to measure lung functionin mice both accurately and noninvasively. We should point outthat the demonstration of a significant correlation between Penhand more conventional measures of lung mechanics (which is oftentouted as support for the use of Penh) does not in any way meanthat Penh can be used as a surrogate for those other measures.Indeed, it is well known that variables may be correlated whilehaving no direct causal relationship to each other. To illustratethis point, consider two common markers of body habitus: bodyweight and height. These two variables are obviously stronglycorrelated, yet the idea of using height as a substitute for bodyweight in a study of obesity is clearly ludicrous. For the abovereasons, we did not even think of trying to calculate Penh inour study. Apart from not being sure exactly how it should bedone, it did not seem to us that calculating Penh would serveany usefulpurpose.

Where we do not agree with Mitzner and Tankersley is on their last point, that Penh should be renamed something like ventilatorytiming or ventilation. Penh is merely an empirical dimensionlessquantity that captures, to a certain extent, the shape of therespiratory cycle in box pressure. The one thing we must not dois give it a name that suggests it is more than that, so the enigmaticPenh is, in our opinion, quite suitable. At this point, who knowswhat Penh is, and whocares?

	FOOTNOTES

10.1152/japplphysiol.00815.2002

REFERENCES

1. Lundblad, LKA, Irvin CG, Adler A, and Bates JHT A reevaluation of the validity of unrestrained plethysmography in mice. J Appl Physiol 93: 1198-1207, 2002[Abstract/Free Full Text].

Lennart K. A. Lundblad
Vermont Lung Center
University of Vermont
Burlington, Vermont 05405
Department of Clinical Physiology
Lund University
Malmö S-22475, Sweden

Andy Adler
Department of Biomedical Engineering
University of Ottawa
Ottawa, Ontario, Canada K1Z 8P9

Charles G. Irvin,
Jason H. T. Bates
Vermont Lung Center
University of Vermont
Burlington, Vermont 05405
E-mail: jhtbates{at}zoo.uvm.edu

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V. V. Jain, T. R. Businga, K. Kitagaki, C. L. George, P. T. O'Shaughnessy, and J. N. Kline
Mucosal immunotherapy with CpG oligodeoxynucleotides reverses a murine model of chronic asthma induced by repeated antigen exposure
Am J Physiol Lung Cell Mol Physiol, November 1, 2003; 285(5): L1137 - L1146.
[Abstract] [Full Text] [PDF]

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