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Reported insulin pump temperature fluctuations lack clinical relevance

Authors Dokken BB, Rosinko M

Received 23 November 2016

Accepted for publication 24 November 2016

Published 20 February 2017 Volume 2017:10 Pages 43—46

DOI https://doi.org/10.2147/MDER.S128526

Checked for plagiarism Yes

Editor who approved publication: Dr Scott Fraser



Betsy B Dokken, Michael Rosinko

Tandem Diabetes Care, Inc., San Diego, CA, USA

In their recent paper, Vereshchetin et al1 suggested that the heat generated by the Tandem Diabetes Care, Inc. (San Diego, CA, USA) t:slim® Insulin Pump during battery charging is high enough to degrade insulin. There are several reasons that the arguments made in this paper are not relevant to patient use of the t:slim Insulin Pump.

Authors’ reply
Paul Vereshchetin, Thomas W McCann Jr, Navdeep Ojha, Ramakrishna Venugopalan, Brian L Levy

Johnson & Johnson Diabetes Care Companies, Chesterbrook, PA, USA

The authors appreciate the response from Tandem Diabetes Care Inc., specifically Dr. Dokken and Mr. Rosinko, to the, paper titled: Comparison of rechargeable versus batteryoperated insulin pumps: temperature fluctuations.1


View original paper by Vereshchetin et al.

Dear editor

In their recent paper, Vereshchetin et al1 suggested that the heat generated by the Tandem Diabetes Care, Inc. (San Diego, CA, USA) t:slim® Insulin Pump during battery charging is high enough to degrade insulin. There are several reasons that the arguments made in this paper are not relevant to patient use of the t:slim Insulin Pump.

First, the temperature probe used by the investigators was attached to the rear of the t:slim Insulin Pump., on the outside of the cartridge. Insulin (water in this experiment) inside the cartridge is surrounded by a plastic sheath and covered by polycarbonate, providing 2 layers of material between the fluid and the temperature probe. Based on data from the study in question, an estimate of the temperature of fluid within the cartridge is pure speculation.

Second, the investigators charged the t:slim insulin pumps in a sealed chamber heated to 35°C (95°F) for a period of 180 minutes (3 hours). The extreme conditions created in the investigators’ laboratory are not applicable to user experiences. It is highly unlikely that users will charge their t:slim Insulin Pumps in an unventilated environment in extreme heat for an extended time. In contrast to the authors’ statement that charging the t:slim Insulin Pump for 3 hours is “not an unlikely scenario”, our findings suggest otherwise. Analysis of data from patient uploads into Tandem’s t:connect® Diabetes Management Application software (Tandem Diabetes Care, Inc., data on file; 2016) found that the average time per charging session for the t:slim Insulin Pump is 30 minutes. The authors’ own data demonstrate that charging the t:slim Insulin Pump under ambient conditions, even for an excessive period of time, did not result in a significant temperature increase.

In addition, labeling of insulin lispro, insulin aspart, and the Tandem Diabetes Care, Inc. t:slim Insulin Pump, t:flex® Insulin Pump, t:slim G4™ Insulin Pump, and t:slim X2™ Insulin Pump (and all other brands of insulin pumps) instructs patients to avoid extreme temperatures. A user of any insulin pump who finds themselves in extreme conditions similar to the heated test in this study should be taking precautions to protect their insulin, as indicated in their pump and insulin labeling.

In summary, the implication that the t:slim Insulin Pump, when used as indicated, operates at a temperature inconsistent with the stability of insulin is not supported by the data presented.1

Disclosure

The authors report no conflicts of interest in this communication.

References

1.

Vereshchetin P, McCann TW, Ojha N, Venugopalan R, Levy BL. Comparison of rechargeable versus battery-operated insulin pumps: temperature fluctuations. Med Devices (Auckl). 2016;9:371–376.

Authors’ reply

Paul Vereshchetin, Thomas W McCann Jr, Navdeep Ojha, Ramakrishna Venugopalan, Brian L Levy

Johnson & Johnson Diabetes Care Companies, Chesterbrook, PA, USA

Correspondence: Paul Vereshchetin, Johnson & Johnson Diabetes Care Companies, 965 Chesterbrook Boulevard, Chesterbrook, PA 19087, USA
Tel +1 484 328 6229
Email [email protected]

Dear editor

The authors appreciate the response from Tandem Diabetes Care Inc., specifically Dr. Dokken and Mr. Rosinko, to the paper titled: Comparison of rechargeable versus battery-operated insulin pumps: temperature fluctuations.1

The purpose of this paper was to investigate what effect(s), if any, certain technologies common to portable consumer devices might have when applied to the medical device space. In particular, recent recalls of portable devices due to rechargeable battery issues including significant overheating leading to fire, e.g. in Samsung Galaxy Note 7,2 suggest that it is necessary to further assess the rechargeable battery technology and its integration into medical devices such as insulin pumps to evaluate potential risks to patient safety.

Apropos of the first point in the response letter, the authors’ original hypothesis was that the temperature inside the plastic sheath would be higher than the external surface temperature of the cartridge. Therefore, the publication included external measurements. However, we did conduct an invasive study measuring the temperature inside the cartridge by making a small incision in the cartridge with an NSK ultrasonic cutter (Nakanishi Corporation, Tokyo, Japan) to insert the thermocouple probe (Omega Engineering Inc., Stamford, CT, USA). The invasive study showed, in agreement with the hypothesis, that the temperature inside the cartridge is even higher than on its surface. In particular, at its largest, the difference between the temperature inside the cartridge of a battery-operated pump and the temperature inside the cartridge of a pump using rechargeable battery constituted 9.5°C (17.1°F) compared to the largest difference of 6.4°C (11.4°F) cited in the published study referenced earlier.

With regard to the opinion that the experiment temperatures are extreme, the investigators do not deem them such – in 2016, in Phoenix (AZ) alone, there were 51 days with average temperatures at or above 35°C (95°F) and 143 days with maximum temperatures at or above 35°C (95°F).3 Rechargeable pumps can be charged through the USB port with a portable charging device, a power bank, which makes the outdoors charging scenario a possibility. Our published study demonstrates that within ~10 minutes of charging in the 35°C (95°F) ambient temperature, the pump surface temperature crosses the insulin degradation threshold. Given the invasive experiment mentioned earlier, the temperature inside the cartridge can be assumed to be crossing the threshold even sooner. Therefore, not only the average time of 30 minutes, but even the recommended time of 10–15 minutes4 is enough to render the insulin in the pump compromised as per NovoLog5 and Humalog6 labeling information: “insulin in the pump reservoir should be discarded after at least every 6 days of use or after exposure to temperatures that exceed 37°C (98.6°F)”.

Based on the published study data, the invasive experiment data included herein, and the laid out arguments, the researchers stand by the conclusion that lithium-ion rechargeable battery pumps show substantial temperature increases during charging relative to battery-operated pumps and that under certain possible temperature and charging use cases, such increases can have negative effect on the insulin being used in the pump potentially leading to compromised therapy.

Disclosure

The study was sponsored by Animas Corporation. The authors report no conflicts of interest in this communication.

References

1.

Vereshchetin P, McCann TW, Ojha N, Venugopalan R, Levy BL. Comparison of rechargeable versus battery-operated insulin pumps: temperature fluctuations. Med Devices (Auckl). 2016;9:371–376.

2.

Rowe D [webpage on the Internet]. Samsung Could Be About to Release the Results From Its Galaxy Note 7 Probe. Fortune. 2016. Available from: http://fortune.com/2016/11/30/samsung-probe-galaxy-note-7/. Accessed December 1, 2016.

3.

weather.gov [homepage on the Internet]. National Weather Service of the National Oceanic and Atmospheric Administration of the US Department of Commerce. Available from: http://w2.weather.gov/. Accessed November 25, 2016.

4.

t:slim G4TM [user guide]. Available from: https://www.tandemdiabetes.com/docs/default-source/product-documents/t-slim-g4-insulin-pump/tslim-g4-insulin-pump-user-guide-b005630_c.pdf?sfvrsn=4. Accessed September 20, 2016.

5.

NovoLog (insulin aspart [rDNA origin] injection) [prescribing information]. Available from: http://www.novo-pi.com/novolog.pdf. Accessed September 20, 2016.

6.

Humalog (insulin lispro injection) [prescribing information]. Available from: http://pi.lilly.com/us/humalog-pen-pi.pdf. Accessed September 20, 2016.

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