Use of an activity monitor to detect response to treatment in dogs with osteoarthritis

Dorothy Cimino Brown Department of Clinical Studies–Philadelphia, School of Veterinary Medicine and Center for Clinical Epidemiology & Biostatistics, School of Medicine, University of Pennsylvania, Philadelphia, PA 19104.

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 DVM, MSCE, DACVS
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Raymond C. Boston Center for Clinical Epidemiology & Biostatistics, School of Medicine, University of Pennsylvania, Philadelphia, PA 19104.

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 PhD
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John T. Farrar Center for Clinical Epidemiology & Biostatistics, School of Medicine, University of Pennsylvania, Philadelphia, PA 19104.

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 MD, PhD
DOI:
https://doi.org/10.2460/javma.237.1.66
Volume/Issue:
Volume 237: Issue 1
Online Publication Date:
01 Jul 2010
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Abstract

Objective—To determine whether an activity monitor (AM) could be used to detect changes in activity in dogs with osteoarthritis treated with carprofen or a placebo.

Design—Randomized controlled trial.

Animals—70 dogs with no clinically important abnormalities other than osteoarthritis for which they were not currently being treated.

Procedures—Dogs wore an AM continuously for 21 days. On days 8 through 21, the dogs were treated with carprofen (n = 35) or a placebo (35). Total activity counts for days 1 through 7 (baseline) were compared with total activity counts for days 15 through 21 (endpoint). The change in total activity count from baseline to endpoint was assessed within each treatment group as well as between groups. Linear regression analysis was performed to test for an association between treatment and percentage change in activity counts while controlling for other variables.

Results—For placebo-treated dogs, median baseline total activity count was not significantly different from median endpoint total activity count (1,378,408 vs 1,310,112, respectively). For dogs receiving carprofen, there was a significant increase in median activity count from baseline to endpoint (1,276,427 vs 1,374,133). When age and baseline activity counts were controlled for, dogs in the carpofen-treated group had a 20% increase in activity counts, compared with placebo-treated dogs (95% confidence interval, 10% to 26%).

Conclusions and Clinical Relevance—Results suggested that the AM used in the present study may be a valid outcome assessment tool for documenting improved activity associated with treatment in dogs with osteoarthritis.

Abstract

Objective—To determine whether an activity monitor (AM) could be used to detect changes in activity in dogs with osteoarthritis treated with carprofen or a placebo.

Design—Randomized controlled trial.

Animals—70 dogs with no clinically important abnormalities other than osteoarthritis for which they were not currently being treated.

Procedures—Dogs wore an AM continuously for 21 days. On days 8 through 21, the dogs were treated with carprofen (n = 35) or a placebo (35). Total activity counts for days 1 through 7 (baseline) were compared with total activity counts for days 15 through 21 (endpoint). The change in total activity count from baseline to endpoint was assessed within each treatment group as well as between groups. Linear regression analysis was performed to test for an association between treatment and percentage change in activity counts while controlling for other variables.

Results—For placebo-treated dogs, median baseline total activity count was not significantly different from median endpoint total activity count (1,378,408 vs 1,310,112, respectively). For dogs receiving carprofen, there was a significant increase in median activity count from baseline to endpoint (1,276,427 vs 1,374,133). When age and baseline activity counts were controlled for, dogs in the carpofen-treated group had a 20% increase in activity counts, compared with placebo-treated dogs (95% confidence interval, 10% to 26%).

Conclusions and Clinical Relevance—Results suggested that the AM used in the present study may be a valid outcome assessment tool for documenting improved activity associated with treatment in dogs with osteoarthritis.

Contributor Notes

Supported by National Institutes of Health Grant No. 1-K08-DA-017720-02.

The authors thank Molly Love for technical assistance.

Address correspondence to Dr. Brown (dottie@vet.upenn.edu).
Cover Journal of the American Veterinary Medical Association
Journal of the American Veterinary Medical Association
Publication Date:
01 Jul 2010
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