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Sampling Plans for Use of Rapid Adenosine Triphosphate (ATP) Monitoring Must Overcome Variability or Suffer Statistical Invalidity

Published online by Cambridge University Press:  18 December 2014

Greg S. Whiteley ,
Chris Derry  and
Trevor Glasbey
Greg S. Whiteley*
Affiliation:
University of Western Sydney, New South Wales, Australia Whiteley Corporation Pty, North Sydney, New South Wales, Australia
Chris Derry
Affiliation:
University of Western Sydney, New South Wales, Australia
Trevor Glasbey
Affiliation:
Whiteley Corporation Pty, North Sydney, New South Wales, Australia
*
Address correspondence to Greg S. Whiteley, MSafetySc, PO Box 1076, North Sydney, New South Wales 2060, Australia (gregswhiteley@aol.com)
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Type
Letters to the Editor
Information
Infection Control & Hospital Epidemiology , Volume 36 , Issue 2 , February 2015 , pp. 236 - 237
Copyright
© 2014 by The Society for Healthcare Epidemiology of America. All rights reserved 

Reply to Visrodia

To the Editor—We write with respect to the article by Visrodia et al.Reference Visrodia, Ofstead, Yellin, Wetzler, Tosh and Baron 1 on using a commercial rapid adenosine triphosphate (ATP) device for validation of cleaning of flexible gastroendoscopes. The importance of timeliness in quality assurance testing in this device area is critical owing to the time pressures on the use of the gastroendoscopes by clinical staff involved in patient care. The work is a useful additional contribution to this growing field of use for ATP devices.Reference Alfa, Fatima and Olson 2

Nonetheless, we highlight concerns with 2 aspects of the method adopted within the work by Visrodia et al.Reference Visrodia, Ofstead, Yellin, Wetzler, Tosh and Baron 1 First, this work, like earlier references, utilizes only a single brand of rapid ATP device with acknowledged manufacturer support. The recommendations on “validated” relative light units (RLU) are entirely device specific and exclude other commercial devices. And, whilst the ATP/RLU readings in Visrodia et al.Reference Visrodia, Ofstead, Yellin, Wetzler, Tosh and Baron 1 may seem dramatic (some >100,000 RLU), the work lacks evaluation of microbial presence that could anchor the study against a quantitated standard.Reference Sciortino and Giles 3

Second, the work does not address any of the major published criticisms of the use of ATP systems as they are currently configured. Several authors have commented on the dangers of overstating the usefulness of these commercial ATP devices, the risks of alternative sources of ATP, the lack of correlation with specific pathogens of concern, the amount of ATP present within any particular cells or bacterial species, and the measurement variability that undermines statistical measures applied to the research.Reference Malik and Shama 4 Reference Whiteley, Derry and Glasbey 7

In this regard, and of specific concern in terms of method in Visrodia et al.,Reference Visrodia, Ofstead, Yellin, Wetzler, Tosh and Baron 1 is the way that ATP measurements and samples were obtained—for example, samples from the brush and flush sampling were divided into only 2 parts, with one part apparently used for a single ATP test and the other part tested for protein residues. The entire sample set of ATP testing appears to be without duplicates or preferably triplicate testing. Reliance by Visrodia et al.Reference Visrodia, Ofstead, Yellin, Wetzler, Tosh and Baron 1 upon the sample means of groups of singular ATP readings is undermined by the knowledge of variability where the standard deviation can be as high as 40% of the data mean for the individual brand of device used.Reference Whiteley, Derry and Glasbey 8 The authors themselves note the risk of singular testing in the body of the discussion: “to sample more than one… and to use more than 1 rapid indicator,” but we wonder how the statistical assumptions hold valid without multiple (replicate) samples taken for the ATP testing.

We also note 2 problems with the scaling of all commercial ATP devices. First, the scale of RLU is completely relative and cannot be used interoperatively between differently branded devices.Reference Alfa, Fatima and Olson 2 , Reference Sciortino and Giles 3 Second, the variability for each of the brands is so high that without a sampling approach that accounts for multiple samples at any one point, the ability of the scientists involved to meaningfully apply statistical methods renders the article subject to first principle flaws.Reference Lautenback, Woeltje and Malani 9 Reporting the RLU readings on a log scale is not the same as taking multiple samples, identifying the median value, and then log plotting the data. Perhaps this was done, but it remains unclear within the text.

We feel obliged to inform those who may be reliant upon the work to take care in not applying the work using one brand of ATP device to another brand of ATP device, as noted in the commentary by Petersen.Reference Petersen 10 Likewise, we caution against relying on the statistical positioning in the field use of ATP without an appropriately constructed sampling plan to account for inherent variability. This overlay of concern will continue to apply until all ATP device manufacturers can agree to a commonly applicable scale that minimizes the impact of variability, no matter what the assignation given to the replacement reading scale.

Acknowledgments

Financial support. None reported.

Potential conflicts of interest. All authors report no conflicts of interest relevant to this article.

References

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