Restrained whole body plethysmography for measure of strain-specific and allergen-induced airway responsiveness in conscious mice

doi:10.1152/japplphysiol.00464.2006

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Restrained whole body plethysmography for measure of strain-specific and allergen-induced airway responsiveness in conscious mice

Jennifer L. S. Lofgren,¹ Melissa R. Mazan,¹ Edward P. Ingenito,² Kara Lascola,¹ Molly Seavey,¹ Ashley Walsh,¹ and Andrew M. Hoffman¹

¹Cummings School of Veterinary Medicine at Tufts University, North Grafton; and ²Brigham and Woman's Hospital, Boston, Massachusetts

Submitted 23 April 2006 ; accepted in final form 2 July 2006

The mouse is the most extensively studied animal species inrespiratory research, yet the technologies available to assessairway function in conscious mice are not universally accepted.We hypothesized that whole body plethysmography employing noninvasiverestraint (RWBP) could be used to quantify specific airway resistance(sRaw-RWBP) and airway responsiveness in conscious mice. Methacholineresponses were compared using sRaw-RWBP vs. airway resistanceby the forced oscillation technique (Raw-FOT) in groups of C57,A/J, and BALB/c mice. sRaw-RWBP was also compared with sRawderived from double chamber plethysmography (sRaw-DCP) in BALB/c.Finally, airway responsiveness following allergen challengein BALB/c was measured using RWBP. sRaw-RWBP in C57, A/J, andBALB/c mice was 0.51 ± 0.03, 0.68 ± 0.03, and0.63 ± 0.05 cm/s, respectively. sRaw derived from Raw-FOTand functional residual capacity (Raw*functional residual capacity)was 0.095 cm/s, approximately one-fifth of sRaw-RWBP in C57mice. The intra- and interanimal coefficients of variationswere similar between sRaw-RWBP (6.8 and 20.1%) and Raw-FOT (3.4and 20.1%, respectively). The order of airway responsivenessemploying sRaw-RWBP was AJ > BALBc > C57 and for Raw-FOTwas AJ > BALB/c = C57. There was no difference between theairway responsiveness assessed by RWBP vs. DCP; however, baselinesRaw-RWBP was significantly lower than sRaw-DCP. Allergen challengecaused a progressive decrease in the provocative concentrationof methacholine that increased sRaw to 175% postsaline valuesbased on sRaw-RWBP. In conclusion, the technique of RWBP wasrapid, reproducible, and easy to perform. Airway responsivenessmeasured using RWBP, DCP, and FOT was equivalent. Allergen responsescould be followed longitudinally, which may provide greaterinsight into the pathogenesis of chronic airway disease.

murine; specific airway resistance; bronchial reactivity; forced oscillation technique; methacholine

Address for reprint requests and other correspondence: A. M. Hoffman, Tufts Univ.'s Cummings School of Veterinary Medicine, 200 Westboro Road, North Grafton, MA 01536 (e-mail: andrew.hoffman{at}tufts.edu)

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