SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4213442743> ?p ?o ?g. }

Showing items 1 to 100 of ±144 with 100 items per page.

W4213442743 abstract "<sec> <title>BACKGROUND</title> Type 1 diabetes (T1D) is a chronic autoimmune disease in which a deficiency in insulin production impairs the glucose homeostasis of the body. Continuous subcutaneous infusion of insulin is a commonly used treatment method. Artificial pancreas systems (APS) use continuous glucose level monitoring and continuous subcutaneous infusion of insulin in a closed-loop mode incorporating a controller (or control algorithm). However, the operation of APS is challenging because of complexities arising during meals, exercise, stress, sleep, illnesses, glucose sensing and insulin action delays, and the cognitive burden. To overcome these challenges, options to augment APS through integration of additional inputs, creating multi-input APS (MAPS), are being investigated. </sec> <sec> <title>OBJECTIVE</title> The aim of this survey is to identify and analyze input data, control architectures, and validation methods of MAPS to better understand the complexities and current state of such systems. This is expected to be valuable in developing improved systems to enhance the quality of life of people with T1D. </sec> <sec> <title>METHODS</title> A literature survey was conducted using the Scopus, PubMed, and IEEE Xplore databases for the period January 1, 2005, to February 10, 2020. On the basis of the search criteria, 1092 articles were initially shortlisted, of which 11 (1.01%) were selected for an in-depth narrative analysis. In addition, 6 clinical studies associated with the selected studies were also analyzed. </sec> <sec> <title>RESULTS</title> Signals such as heart rate, accelerometer readings, energy expenditure, and galvanic skin response captured by wearable devices were the most frequently used additional inputs. The use of invasive (blood or other body fluid analytes) inputs such as lactate and adrenaline were also simulated. These inputs were incorporated to switch the mode of the controller through activity detection, directly incorporated for decision-making and for the development of intermediate modules for the controller. The validation of the MAPS was carried out through the use of simulators based on different physiological models and clinical trials. </sec> <sec> <title>CONCLUSIONS</title> The integration of additional physiological signals with continuous glucose level monitoring has the potential to optimize glucose control in people with T1D through addressing the identified limitations of APS. Most of the identified additional inputs are related to wearable devices. The rapid growth in wearable technologies can be seen as a key motivator regarding MAPS. However, it is important to further evaluate the practical complexities and psychosocial aspects associated with such systems in real life. </sec>" @default.
W4213442743 created "2022-02-25" @default.
W4213442743 creator A5019936781 @default.
W4213442743 creator A5051590202 @default.
W4213442743 creator A5053193359 @default.
W4213442743 creator A5055734771 @default.
W4213442743 creator A5055848500 @default.
W4213442743 creator A5059778915 @default.
W4213442743 date "2021-03-16" @default.
W4213442743 modified "2023-09-26" @default.
W4213442743 title "Integrating Multiple Inputs Into an Artificial Pancreas System: Narrative Literature Review (Preprint)" @default.
W4213442743 cites W1507380697 @default.
W4213442743 cites W1964693647 @default.
W4213442743 cites W1982063015 @default.
W4213442743 cites W1985857846 @default.
W4213442743 cites W1991725952 @default.
W4213442743 cites W1994612927 @default.
W4213442743 cites W1995121211 @default.
W4213442743 cites W2000933107 @default.
W4213442743 cites W2010762887 @default.
W4213442743 cites W2015463169 @default.
W4213442743 cites W2016851323 @default.
W4213442743 cites W2028397193 @default.
W4213442743 cites W2038094456 @default.
W4213442743 cites W2044540970 @default.
W4213442743 cites W2072195069 @default.
W4213442743 cites W2074952300 @default.
W4213442743 cites W2092559456 @default.
W4213442743 cites W2111311157 @default.
W4213442743 cites W2112508118 @default.
W4213442743 cites W2120973917 @default.
W4213442743 cites W2125624587 @default.
W4213442743 cites W2154399211 @default.
W4213442743 cites W2155639879 @default.
W4213442743 cites W2156353972 @default.
W4213442743 cites W2158443705 @default.
W4213442743 cites W2162557622 @default.
W4213442743 cites W2163532367 @default.
W4213442743 cites W2170006529 @default.
W4213442743 cites W2182279560 @default.
W4213442743 cites W2202491126 @default.
W4213442743 cites W2237750930 @default.
W4213442743 cites W2281837728 @default.
W4213442743 cites W2333815048 @default.
W4213442743 cites W2419628072 @default.
W4213442743 cites W2463876450 @default.
W4213442743 cites W2479902120 @default.
W4213442743 cites W2530172850 @default.
W4213442743 cites W2531054041 @default.
W4213442743 cites W2593924932 @default.
W4213442743 cites W2599850051 @default.
W4213442743 cites W2604712698 @default.
W4213442743 cites W2747302659 @default.
W4213442743 cites W2766293171 @default.
W4213442743 cites W2783274781 @default.
W4213442743 cites W2790915589 @default.
W4213442743 cites W2791784198 @default.
W4213442743 cites W2792431097 @default.
W4213442743 cites W2799357239 @default.
W4213442743 cites W2807893746 @default.
W4213442743 cites W2890627459 @default.
W4213442743 cites W2896581126 @default.
W4213442743 cites W2908531770 @default.
W4213442743 cites W2914059200 @default.
W4213442743 cites W2916165156 @default.
W4213442743 cites W2939860515 @default.
W4213442743 cites W2942916770 @default.
W4213442743 cites W2947475775 @default.
W4213442743 cites W2963898471 @default.
W4213442743 cites W2971907832 @default.
W4213442743 cites W2980281598 @default.
W4213442743 cites W2996840266 @default.
W4213442743 cites W2998006588 @default.
W4213442743 cites W3022678696 @default.
W4213442743 cites W3022903699 @default.
W4213442743 cites W3093054111 @default.
W4213442743 cites W3111403304 @default.
W4213442743 cites W3128611430 @default.
W4213442743 cites W4206105267 @default.
W4213442743 cites W4214912591 @default.
W4213442743 cites W4230266377 @default.
W4213442743 cites W4241472456 @default.
W4213442743 cites W4249207531 @default.
W4213442743 cites W4251590866 @default.
W4213442743 cites W4253912740 @default.
W4213442743 cites W4256087696 @default.
W4213442743 cites W71202391 @default.
W4213442743 doi "https://doi.org/10.2196/preprints.28861" @default.
W4213442743 hasPublicationYear "2021" @default.
W4213442743 type Work @default.
W4213442743 citedByCount "0" @default.
W4213442743 crossrefType "posted-content" @default.
W4213442743 hasAuthorship W4213442743A5019936781 @default.
W4213442743 hasAuthorship W4213442743A5051590202 @default.
W4213442743 hasAuthorship W4213442743A5053193359 @default.
W4213442743 hasAuthorship W4213442743A5055734771 @default.
W4213442743 hasAuthorship W4213442743A5055848500 @default.
W4213442743 hasAuthorship W4213442743A5059778915 @default.
W4213442743 hasBestOaLocation W42134427432 @default.
W4213442743 hasConcept C126322002 @default.