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| Name | Class |
|---|---|
| ETH Zurich | OTHER |
| University of St.Gallen | OTHER |
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To analyse driving behavior of individuals with type 1 diabetes in eu- and progressive hypoglycaemia using a validated research driving simulator. Based on the driving variables provided by the simulator the investigators aim at establishing algorithms capable of discriminating eu- and hypoglycemic driving patterns using machine learning neural networks (deep machine learning classifiers).
Hypoglycaemia is among the most relevant acute complications of diabetes mellitus. During hypoglycaemia physical, psychomotor, executive and cognitive function significantly deteriorate. These are important prerequisites for safe driving. Accordingly, hypoglycaemia has consistently been shown to be associated with an increased risk of driving accidents and is, therefore, regarded as one of the relevant factors in traffic safety. Despite important developments in the field of diabetes technology, the problem of hypoglycaemia during driving persists. Automotive technology is highly dynamic, and fully autonomous driving might, in the end, resolve the issue of hypoglycemia-induced accidents. However, autonomous driving (level 4 or 5) is likely to be broadly available only to a substantially later time point than previously thought due to increasing concerns of safety associated with this technology. Therefore, solutions bridging the upcoming period by more rapidly and directly addressing the problem of hypoglycemia-associated traffic incidents are urgently needed.
On the supposition that driving behaviour differs significantly between euglycaemic state and hypoglycaemic state, the investigators assume that different driving patterns in hypoglycemia compared to euglycemia can be used to generate hypoglycemia detection models using machine learning neural networks (deep machine learning classifiers).
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Intervention group | Experimental |
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| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Controlled hypoglycaemic state while driving with a driving simulator | Other | Patients will arrive in the morning after an overnight fast. During the controlled hypoglycaemic state, participants will drive on a designated circuit using a driving simulator. Initially, euglycaemic state (5.0-8.0 mmol/L) will be kept stable and then blood glucose will be declined progressively targeting at a level between 2.0-2.5mmol/L by administering an insulin bolus. Glucose will be kept stable at the hypoglycaemic level for 30 minutes. Thereafter, it will be raised again and kept stable for another 30 minutes at an euglycaemic level between 5.0-8.0mmol/L. During the procedure, we will analyse counterregulatory hormones. Heart rate, skin conductance, CGM values, eye movement and facial expression, will be recorded by a smart-watch, a CGM device, an eye-tracker and an onboard camera, respectively. Participants will be blinded to the glucose values during the procedure. They will have to rate their symptoms and their performance on a 0-6 scale every 15 minutes. |
| Measure | Description | Time Frame |
|---|---|---|
| Accuracy of the HEADWIND-model: Diagnostic accuracy of the hypoglycaemia warning system (HEADWIND) to detect hypoglycaemia (blood glucose <3.9mmol/l and <3.0mmol/l) quantified as the area under the receiver operator characteristics curve (AUC ROC). | Accuracy of the HEADWIND-model will be assessed using driving data recorded in progressive hypoglycemia and driving data will be analysed using applied machine learning technology for hypoglycemia detection. | 240 minutes |
| Measure | Description | Time Frame |
|---|---|---|
| Change of time driving over midline | Change of time over midline during driving in hypoglycemia will be compared to euglycemia | 240 minutes |
| Change of swerving | Change of swerving during driving in hypoglycemia will be compared to euglycemia |
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Inclusion Criteria:
Exclusion Criteria:
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| Name | Affiliation | Role |
|---|---|---|
| Christoph Stettler, Prof. MD | Inselspital, Bern University Hospital, University of Bern | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| University Department of Endocirnology, Diabetology, Clinical Nutrition and Metabolism | Bern | Switzerland |
| PubMed Identifier | Type | Citation | Retractions |
|---|---|---|---|
| 38194257 | Derived | Berube C, Lehmann VF, Maritsch M, Kraus M, Feuerriegel S, Wortmann F, Zuger T, Stettler C, Fleisch E, Kocaballi AB, Kowatsch T. Effectiveness and User Perception of an In-Vehicle Voice Warning for Hypoglycemia: Development and Feasibility Trial. JMIR Hum Factors. 2024 Jan 9;11:e42823. doi: 10.2196/42823. |
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| ID | Term |
|---|---|
| D003920 | Diabetes Mellitus |
| D003922 | Diabetes Mellitus, Type 1 |
| D007003 | Hypoglycemia |
| ID | Term |
|---|---|
| D044882 | Glucose Metabolism Disorders |
| D008659 | Metabolic Diseases |
| D009750 | Nutritional and Metabolic Diseases |
| D004700 | Endocrine System Diseases |
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| 240 minutes |
| Change of spinning | Change of spinning during driving in hypoglycemia will be compared to euglycemia | 240 minutes |
| Defining the glycemic level when driving performance is decreased | Based on significantly altered driving parameters in serious hypoglycemia (< 3.0 mmol/L) compared to euglycemia (5.5mmol/L) plasma-glucose level (mmol/L) when driving performance begins to be impaired will be assessed | 240 minutes |
| Driving performance before and after hypoglycemia | Based on significantly altered driving parameters in serious hypoglycemia (< 3.0 mmol/L) driving performance before and after hypoglycemia will be assessed | 240 minutes |
| Change of heart-rate | Change of heart-rate during driving in hypoglycemia will be compared to euglycemia | 240 minutes |
| Change of heart-rate variability | Change of heart-rate variability during driving in hypoglycemia will be compared to euglycemia. | 240 minutes |
| Change of electrodermal activity (EDA) | Change of EDA during driving in hypoglycemia will be compared to euglycemia. | 240 minutes |
| Change of skin temperature | Change of skin temperature during driving in hypoglycemia will be compared to euglycemia. | 240 minutes |
| CGM accuracy during hypoglycaemic state | Accuracy (MARD) of CGM Sensor (dexcom G6) in euglycemia (3.9 - 7 mmol/L), hypoglycemia (3.0 - 3.9mmol/L) and severe hypoglycemia (< 3.0 mmol/L) will be assessed based on plasma glucose measurements. | 240 minutes |
| CGM time-delay during hypoglycaemic state | Time-delay (minutes) of CGM Sensor (dexcom G6) during progressive hypoglycemia will be assessed compared to plasma glucose. | 240 minutes |
| Change of glucagon | Change of glucagon before driving, during driving in euglycemia (5.5mmol/L), in hypoglycemia (< 3.9mmol/L), serious hypoglycemia (< 3mmol/L) and after hypoglycemia will be assessed. | 240 minutes |
| Change of growth hormone (GH) | Change of GH before driving, during driving in euglycemia (5.5mmol/L), in hypoglycemia (< 3.9mmol/L), serious hypoglycemia (< 3mmol/L) and after hypoglycemia will be assessed. | 240 minutes |
| Change of catecholamines | Change of catecholamines before driving, during driving in euglycemia (5.5mmol/L), in hypoglycemia (< 3.9mmol/L), serious hypoglycemia (< 3mmol/L) and after hypoglycemia will be assessed. | 240 minutes |
| Change of cortisol | Change of cortisol before driving, during driving in euglycemia (5.5mmol/L), in hypoglycemia (< 3.9mmol/L), serious hypoglycemia (< 3mmol/L) and after hypoglycemia will be assessed. | 240 minutes |
| Glycemic level at time point of hypoglycemia detection by the HEADWIND-model | Blood glucose at time point of hypoglycemia detection by the HEADWIND-model will be determined. | 240 minutes |
| Comparison CGM and HEADWIND-model regarding time-point of hypoglycemia detection | Time point of hypoglycemia detection by CGM will be compared to time point of hypoglycemia detection by the HEADWIND-model. | 240 minutes |
| Comparison CGM and HEADWIND-model regarding glycemia | Blood glucose at time point of hypoglycemia detection by the HEADWIND- model compared to glucose value of CGM at same time point will be assessed. | 240 minutes |
| Accuracy-comparison of HEADWIND-model and HEADWINDplus-model | Diagnostic accuracy of the hypoglycaemia warning system (HEADWIND) to detect hypoglycaemia (blood glucose < 3.9 mmol/l) quantified as the area under the receiver operator characteristics curve (AUC ROC) using only driving parameters (HEADWIND-model) will be compared to the HEADWIND-model with additional integration of CGM and physiological parameters (heart-rate, heart-rate variability, electrodermal activity (EDA), skin temperature and facial expression) (HEADWINDplus-model) | 240 minutes |
| Diagnostic accuracy in detecting hypoglycemia (blood glucose <3.9 mmol/l and <3.0 mmol/l) quantified as the area under the receiver operator characteristics curve using physiological data | Accuracy of hypoglycemia detection using physiological data (heart-rate, heart-rate variability, skin temperature, EDA) recorded with wearable devices during the study period will be analysed using applied machine learning technology. | 240 minutes |
| Diagnostic accuracy in detecting hypoglycemia (blood glucose < 3.9 mmol/l and < 3.0 mmol/l) quantified as the area under the receiver operator curve (AUC-ROC) using video data | Using video data recorded by a camera and a thermal camera accuracy in hypoglycaemia detection will be analysed with applied machine learning technology. | 240 minutes |
| Diagnostic accuracy in detecting hypoglycemia (blood glucose < 3.9 mmol/l and < 3.0 mmol/l) quantified as the area under the receiver operator curve (AUC-ROC) using eye-tracking data | Using eye-tracking data recorded by a camera and an eye-tracker (to record gaze behaviour) accuracy in hypoglycemia detection will be analysed with applied machine learning technology. | 240 minutes |
| Self-estimation of glucose and hypoglycemia | Correlation between self-estimated glucose values and measured blood glucose will be assessed. | 240 minutes |
| Self-estimation of driving performance | Correlation between self-estimated driving performance and measured driving performance based on significantly altered driving parameters in serious hypoglycemia (< 3.0 mmol/L) compared to euglycemia (5.5mmol/L). Self-estimated driving performance will be assessed on a absolute 7-point scale from 0-6 (a lower value means a better outcome). | 240 minutes |
| Time point of need-to-treat | Time point of self-perceived need-to-treat (hypoglycemia) compared to time point of hypoglycemia detection by the HEADWIND-model and CGM. | 240 minutes |
| Self-perception of hypoglycemia symptoms compared to baseline hypoglycemia awareness | Correlation and comparison of perceived hypoglycemia symptoms on a scale from 0-6 (0 = no symptoms, 6 = extreme symptoms) to baseline hypoglycemia awareness score. Baseline hypoglycemia awareness will be assessed using a validated questionnaire (Clarke-Score) with a score over 3 points indicating decreased hypoglycemia awareness. | 240 minutes |
| Incidence of Adverse Events (AEs) | Adverse Events will be recorded at each study visit. | 5 weeks |
| Incidence of Serious Adverse Events (SAEs) | Serious Adverse Events will be recorded at each study visit. | 5 weeks |
| Perceived ease of use of the early hypoglycaemia warning system (EWS) | Perceived ease of use of the EWS will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| Perceived usefulness of the EWS | Perceived usefulness of the EWS will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| Perceived enjoyment during EWS usage | Perceived enjoyment during EWS usage will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| Intention to adopt the EWS | Intention to adopt the EWS will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| Intention to continuously use the EWS | Intention to continuously use the EWS will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| Reception of recommendations of the EWS | Reception of recommendations of the EWS will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| Processing of recommendations of the EWS | Processing of recommendations of the EWS will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| Perceived understandability of the recommendations of the EWS | Perceived understandability of the EWS will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| Perceived familiarity of the recommendations of the EWS | Perceived familiarity of the recommendations of the EWS will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| Cognitive and emotional trust in the recommendations of the EWS | Cognitive and emotional trust in the recommendations of the EWS will be assessed via questionnaire based self-reports (questionnaire for user interaction satisfaction) measured on the 9-point Likert scale from strongly disagree to strongly agree with a scale range from 0 to 9 and with higher values representing a better outcome. The total score will be averaged. | Throughout the study, expected to be up to 12 months |
| D001327 | Autoimmune Diseases |
| D007154 | Immune System Diseases |