Continuous glucose monitor

Abbott Laboratories' FreeStyle CGM. The sensor and transmitter are fixed to the upper arm and the receiver shows current blood glucose level and a graph of recent blood glucose levels.

A continuous glucose monitor (CGM) is a device used for monitoring blood glucose on a continual basis by insulin-requiring people with diabetes, e.g. people with type I, type II diabetes or other types of diabetes (e.g. gestational diabetes). A continuous glucose monitor consists of three parts: a small electrode placed under the skin, a transmitter sending readings at regular intervals (ranging from every 5 to 15 min), and a separate receiver. Currently approved CGMs use an enzymatic technology which reacts with glucose molecules in the interstitial fluid generating an electric current. This electric current (proportional to the glucose concentration) is then relayed from a transmitter attached to the sensor out to a reader which displays the data to the patient.[1]

Traditional fingerprick testing of blood glucose levels measures the level at a single point in time. CGM use allows trends in blood glucose to be displayed over time. Users must calibrate CGM devices with traditional blood glucose measurements.[2]

CGM is an increasingly adopted technology which has shown to have benefits for people with diabetes. Some studies have demonstrated reduced time spent in hypoglycemia or a lower glycated hemoglobin, both favorable outcomes.[3] However, there are important limitations: CGM systems are not sufficiently accurate for detecting hypoglycemia, a common side-effect of diabetes treatment.[4] This is especially problematic as some devices offer alarm functions to warn of hypoglycemic episodes and people might rely on those alarms. Therefore some manufacturers warn users of relying only on CGM-measurements and the National Institute for Health and Care Excellence recommends to validate hypoglycaemic values via fingerprick testing of blood glucose level.[5] Another limitation is that glucose levels are taken from the interstitial fluid rather than the blood. As it takes time for glucose to travel from the bloodstream into the interstitial fluid, there is an inherent lag behind the current blood glucose level and the level measured by the CGM. This lag time varies based on the person and the device, and is generally 5–20 minutes.[6]

Flash glucose monitoring

While a CGM continuously monitors blood glucose and transmits blood glucose readings to a reader, a flash glucose monitor (FGM) only transmits readings upon user interaction (i.e. scanning the sensor).[7][8][9] Abbott's FreeStyle Libre is an example of an FGM system.[9]

Occasionally, FGM is referred to as a subset of CGM, with a distinction drawn between "real-time" CGM and "flash" CGM. However, CGM and FGM are fundamentally different systems offering unique advantages and disadvantages to patients, and clinicians hold CGM and FGM to be distinct categories.[7][9]

History

United States

The first CGM system was approved by the FDA in 1999. Continued development has extended the length of time sensors can be worn, options for receiving and reading data, and settings for alerting users of high and low glucose levels.

The first iteration of the Medtronic MiniMed took glucose readings every ten seconds with average readings reported every five minutes. Sensors could be worn for up to 72 hours.[10]

A second system, developed by Dexcom, was approved in 2006. The sensor was approved for use for up to 72 hours, and the receiver needed to be within five feet for transmission of data.

In 2008, the third model was approved, Abbott Laboratories' Freestyle Navigator. Sensors could be worn for up to five days.[10]

In 2012, Dexcom released a new device that allowed for the sensor to be worn for seven days and had a transmission distance of 20 feet. Dexcom later introduced an app allowing data from the sensor to be transmitted to an iPhone. This system was approved for paediatric use in 2015.[10]

In September 2017, the FDA approved the first CGM that does not require calibration with fingerstick measurement, the FreeStyle Libre. The Libre is considered a "flash monitoring" system (FGM), and thus not a true ("real-time") CGM system.[7] This device could be worn for up to ten days, but required 12 hours to start readings.[11] and was followed by an updated device that could be worn for up to 14 days, and needed only one hour to start a new sensor.[12][13][14] The FreeStyle Libre 2 was approved in Europe in October 2018, and enabled configuration of alerts when glucose is out of range.

In June 2018, the FDA approved the Eversense CGM system for use in people 18 years of age and older with diabetes. This is the first FDA-approved CGM to include a fully implantable sensor to detect glucose, which can be worn for up to 90 days.[15][16] The Eversense XL, a 180-day version of the system, was approved in Europe in October 2017.[17]

United Kingdom

Current NHS guidelines advise against routinely offering CGM to patients; however, patients including adults and children may be offered CGM if they experience debilitating hypoglycaemia, hypoglycaemia unawareness, or hyperglycaemia that persists despite testing blood glucose more than 10 times per day.[18] However, the NHS offers the FreeStyle Libre flash monitoring (FGM) system to patients, subject to looser criteria.[19]

Device characteristics

  • Continuous vs flash monitoring: Dexcom and Eversense use continuous monitoring where information on the glucose levels are continuously updated. Continuous monitoring allows to set automatic alarms that are triggered when the glucose level goes out of pre-configured thresholds. In contrast, with flash monitoring such as the Freestyle Libre, the glucose level is read automatically by the sensor; however, data is only transmitted to the user on user request. The glucose information store on the sensor contains all the data since the previous read (up to 8 hours). FreeStyle Libre 2 allows configuration of alarms when glucose reaches a pre-determined level.
  • Internal vs external sensors: Dexcom and Freestyle Libre use external sensors while Eversense uses an internal one, although a transmitter must be placed on top of the skin where the sensor lies.

Closed loop system

The CGM is a key element in the development of a "closed-loop" system for the treatment of type I diabetes. A closed-loop system involves blood glucose monitored by CGM and the data sent to an insulin pump for calculated delivery of insulin without user intervention.[10] A number of Insulin pumps currently offer an "auto mode" however this is not yet a fully closed loop system. A number of open source implementations exist; including the artificial pancreas system[20] and OpenAPS.[21]

See also

References

  1. Klonoff (2017). "Continuous glucose monitoring: A review of the technology and clinical use". Diabetes Res Clin Pract. 133: 178-192. doi:10.1016/j.diabres.2017.08.005. PMID 28965029. Retrieved 17 May 2021.
  2. Thomas Diaz, Alicia M., ed. (November 2017). "Continuous Glucose Monitoring". Hormone Health Network. Endocrine Society. Retrieved 24 August 2018.
  3. Klonoff (2017). "Continuous glucose monitoring: A review of the technology and clinical use". Diabetes Res Clin Pract. 133: 178-192. doi:10.1016/j.diabres.2017.08.005. PMID 28965029. Retrieved 17 May 2021.
  4. Lindner, Nicole (2021). "Non-invasive and minimally invasive glucose monitoring devices: a systematic review and meta-analysis on diagnostic accuracy of hypoglycaemia detection". Syst Rev. 145. doi:10.1186/s13643-021-01644-2. PMC 8111899. Retrieved 17 May 2021.
  5. National Institute for Health and Care Excellence. "FreeStyle Libre for glucose monitoring". Retrieved 17 May 2021.
  6. "Glucose: Continuous Glucose Monitoring". Cleveland Clinic. Retrieved 24 August 2018.
  7. 1 2 3 Heinemann, Lutz; Freckmann, Guido (9 September 2020). "CGM Versus FGM; or, Continuous Glucose Monitoring Is Not Flash Glucose Monitoring". Journal of Diabetes Science and Technology. 9 (5): 947–950. doi:10.1177/1932296815603528. PMC 4667350. PMID 26330484.
  8. Staal, Odd Martin; Hansen, Heidi Marie Umbach; Christiansen, Sverre Christian; Fougner, Anders Lyngvi; Carlsen, Sven Magnus; Stavdahl, Øyvind (2018). "Differences Between Flash Glucose Monitor and Fingerprick Measurements". Biosensors. 8 (4): 93. doi:10.3390/bios8040093. PMC 6316667. PMID 30336581.
  9. 1 2 3 "Flash glucose monitoring". Diabetes UK. Retrieved 9 September 2020.
  10. 1 2 3 4 Olczuk, David; Priefer, Ronny (April–June 2018). "A history of continuous glucose monitors (CGMs) in self-monitoring of diabetes mellitus". Diabetes & Metabolic Syndrome: Clinical Research & Reviews. 12 (2): 181–187. doi:10.1016/j.dsx.2017.09.005. PMID 28967612.
  11. Goodin, Tara (27 September 2017). "FDA approves first continuous glucose monitoring system for adults not requiring blood sample calibration". U.S. Food and Drug Administration. Retrieved 24 August 2018.
  12. Health, Center for Devices and Radiological. "Recently-Approved Devices - Freestyle Libre 14 Day Flash Glucose Monitoring System - P160030/S017". www.fda.gov. Retrieved 15 December 2018.
  13. FreeStyle Libre 14-day Flash Glucose Monitoring system
  14. Kunzmann, Kevin (30 July 2018). "FDA Approves 14-Day Freestyle Libre Glucose Monitoring System". MD Magazine. Retrieved 24 August 2018.
  15. McDermott, Jimmy; Levine, Brian; Brown, Adam (6 July 2018). "FDA Approves Senseonics' Eversense 90-Day Implantable CGM, On-Body Transmitter, and Smartphone Apps". diaTribe. Retrieved 24 August 2018.
  16. Caccomo, Stephanie (21 June 2018). "FDA approves first continuous glucose monitoring system with a fully implantable glucose sensor and compatible mobile app for adults with diabetes". U.S. Food and Drug Administration. Retrieved 24 August 2018.
  17. Pallant, Ben (18 October 2017). "A 180-Day CGM: Senseonics' Eversense XL Approved in Europe". diaTribe. Retrieved 24 August 2018.
  18. "Can I get a continuous glucose monitor (CGM) on the NHS?". JDRF, the type 1 diabetes charity. 14 April 2020. Retrieved 9 September 2020.
  19. "Can I get Libre on the NHS?". JDRF, the type 1 diabetes charity. 14 April 2020. Retrieved 9 September 2020.
  20. "Research spotlight – the artificial pancreas". Diabetes UK. Retrieved 20 February 2020.
  21. "OpenAPS.org – #WeAreNotWaiting to reduce the burden of Type 1 diabetes". Retrieved 20 February 2020.
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