The prevalence of diabetes in the United States and the world is high. Often the burden of this disease falls on those who are economically disadvantaged, contributing to disparities in access to care. Considering the risk for foot complications related to diabetes, foot temperature monitoring has been shown to be effective in mitigating risk for plantar ulceration.
Higher-cost thermometers have been assessed for reliability, while very low-cost thermometers have not. Validation of low-cost thermometers could improve access to this preventive measure. In this study, inexpensive commercially available infrared thermometers were shown to be a reliable and valid means to https://biodas.org/ assess local skin temperature.
The Accuracy of a Wireless Axillary Thermometer for Core Temperature Monitoring in Pediatric Patients Having Noncardiac Surgery: An Observational Study
Purpose: A wireless and wearable axillary thermometer (iThermonitor) has been validated for perioperative core temperature monitoring in adults. The purpose of this study was to evaluate its accuracy in pediatrics having non-cardiac surgery.
Design: Prospective observational study.
Methods: From January 2019 to December 2019, 70 children aged younger than 14 years undergoing surgery in a tertiary hospital were selected. Pairs of esophageal temperatures (TEso), rectal temperatures (TRec), and axillary temperatures monitored by the iThermonitor (TiTh) were collected every 5 min during surgery. Taking TEso as reference, the bias between TEso and TiTh and the proportion of bias within ±0.5°C were calculated. Bland-Altman method was used to analyze the 95% of limits of agreement (LOA) between TiTh and TEso. The same analyses were done for TRec. FINDINGS: A total of 2232 pairs of temperatures were collected. The bias (mean ± SD) between TiTh and TEso was -0.07 °C ± 0.25°C, and 95% LOA was -0.07°C ± 0.50°C. The proportion of bias within ±0.5°C accounted for 96% (95% Confidence Interval [CI], 92-98%). Higher bias and 95% LOA, and lower proportion of bias within ± 0.5°C were found between TRec and TEso than those between TiTh and TEso.
Conclusion: During pediatric non-cardiac surgery, axillary temperature derived from iThermonitor is in good agreement with esophageal temperature and can be used as an alternative to core temperature.
Evaluation of a Wearable Non-Invasive Thermometer for Monitoring Ear Canal Temperature during Physically Demanding (Outdoor) Work
Aimed at preventing heat strain, health problems, and absenteeism among workers with physically demanding occupations, a continuous, accurate, non-invasive measuring system may help such workers monitor their body (core) temperature. The aim of this study is to evaluate the accuracy and explore the usability of the wearable non-invasive Cosinuss° °Temp thermometer. Ear canal temperature was monitored in 49 workers in real-life working conditions. After individual correction, the results of the laboratory and field study revealed high correlations compared to ear canal infrared thermometry for hospital use.
After performance of the real-life working tasks, this correlation was found to be moderate. It was also observed that the ambient environmental outdoor conditions and personal protective clothing influenced the accuracy and resulted in unrealistic ear canal temperature outliers. It was found that the Cosinuss° °Temp thermometer did not result in significant interference during work. Therefore, it was concluded that, without a correction factor, the Cosinuss° °Temp thermometer is inaccurate. Nevertheless, with a correction factor, the reliability of this wearable ear canal thermometer was confirmed at rest, but not in outdoor working conditions or while wearing a helmet or hearing protection equipment.
Mobile Health-Based Thermometer for Monitoring Wound Healing After Endovascular Therapy in Patients With Chronic Foot Ulcer: Prospective Cohort Study
Background: Foot temperature may increase after endovascular therapy, but the relationship between foot temperature and wound healing is unclear.
Objective: This study was performed to evaluate the feasibility of a mobile health (mHealth)-based thermometer for foot temperature monitoring in patients with chronic foot ulcer before and after endovascular therapy and to determine the association between temperature change and wound healing time.
Methods: This was a prospective cohort study. Patients who had a chronic foot ulcer (>3 months) and underwent endovascular therapy between June 2019 and December 2019 were included. The participants received standard medical care and endovascular therapy for revascularization. The mHealth-based thermometer, composed of 4 temperature-sensing chips, was put on the foot before and after endovascular therapy. Data from the chips were transferred to an associated mobile phone app via Bluetooth. Wound healing time was estimated using the Kaplan-Meier method, and the associations between baseline characteristics and clinical outcomes were evaluated using a Cox proportional hazard model.
Results: A total of 163 patients with chronic foot ulcer who underwent endovascular therapy were enrolled and followed up until wound healing was complete or for 180 days. The mean foot temperature before endovascular therapy was 30.6 (SD 2.8 °C). Foot temperature increased significantly (mean 32.1 °C, SD 2.8 °C; P=.01) after the procedure. Wound healing time was significantly different in the Kaplan-Meier curves of the patient group with temperature changes ≥2 °C and the group with temperature changes ≤2 °C (log-rank P<.001). A foot temperature increase ≥2 °C after endovascular therapy was associated with increased wound healing in univariate analysis (hazard ratio [HR] 1.78, 95% CI 1.24-2.76, P=.02), and the association remained significant in multivariate analysis (HR 1.69, 95% CI 1.21-2.67, P=.03).
Conclusions: The mHealth-based thermometer was feasible and useful for foot temperature monitoring, which may provide health care professionals with a new endpoint for endovascular therapy. Foot temperature increases ≥2 °C after endovascular therapy were associated with faster wound healing in patients with chronic foot ulcer. Further studies are needed, however, to confirm these findings.
Tympanic thermometers support fast and accurate temperature monitoring in acute and alternative care
This article explores body temperature and the physiological process of thermoregulation. Normal body temperature and body temperature changes are discussed, including comorbidities associated with body temperature and signs of hyperthermia and hypothermia, and the factors that affect intraoperative temperature regulation.
The evidence base behind thermometry is discussed and is applied to contemporary clinical conditions and symptoms, including: sepsis and suspected COVID-19. After discussing clinical considerations and regulations that encompass thermometry, three case studies present the use of the Genius 3 Tympanic Thermometer in clinical practice, with user feedback supporting its benefits, which include speed, accuracy and ease of use.
Mitochondria-Anchored Molecular Thermometer Quantitatively Monitoring Cellular Inflammations
Temperature in mitochondria can be a critical indicator of cell metabolism. Given the highly dynamic and inhomogeneous nature of mitochondria, it remains a big challenge to quantitatively monitor the local temperature changes during different cellular processes. To implement this task, we extend our strategy on mitochondria-anchored thermometers from “on-off” probe Mito-TEM to a ratiometric probe Mito-TEM 2.0 based on the Förster resonance energy transfer mechanism. Mito-TEM 2.0 exhibits not only a sensitive response to temperature through the ratiometric changes of dual emissions but also the specific immobilization in mitochondria via covalent bonds.
Both characters support accurate and reliable detection of local temperature for a long time, even in malfunctioning mitochondria. By applying Mito-TEM 2.0 in fluorescence ratiometric imaging of cells and zebrafishes, we make a breakthrough in the quantitative visualization of mitochondrial temperature rises in different inflammation states.
Low Range Thermometer -100 to 50 - EACH |
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THE1170 | Scientific Laboratory Supplies | EACH | 143.94 EUR |
SOM02.0 Selected Ion Monitoring 2 Components - 1ML |
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CLPS-SOM-ISB | Scientific Laboratory Supplies | 1ML | 133.65 EUR |
3M Clean-Trace Hygiene Monitoring and Management System - EACH |
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FSA1260 | Scientific Laboratory Supplies | EACH | 7275.15 EUR |
SOM02.0 Deuterated Monitoring Compounds Standard Spiking Solution - 1ML |
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CLPS-SOM-ISA | Scientific Laboratory Supplies | 1ML | 1463.4 EUR |
THERMOMETER, DIGITAL |
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T786 | PhytoTechnology Laboratories | 1EA | 84.82 EUR |
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T8710 | Consort | ea | 1538.4 EUR |
scanning thermometer |
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T8720 | Consort | ea | 1538.4 EUR |
Thermometer -1 to 101C (0.2) |
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THE1374 | Scientific Laboratory Supplies | EACH | 18.45 EUR |
Spirit Thermometer -10 to 110C |
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THE1080 | Scientific Laboratory Supplies | EACH | 3.48 EUR |
Thermometer (TDC 150) - EACH |
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THE1802 | Scientific Laboratory Supplies | EACH | 55.52 EUR |
Thermometer/hygrometer - EACH |
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DD98463 | Scientific Laboratory Supplies | EACH | 29.7 EUR |
Thermometer -1 to 101C (0.2) - EACH |
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THE1372 | Scientific Laboratory Supplies | EACH | 28.23 EUR |
Thermometer -1 to 51C (0.1) |
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THE1366 | Scientific Laboratory Supplies | EACH | 18.45 EUR |
Thermometer -1 to 51C (0.2) |
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THE1370 | Scientific Laboratory Supplies | EACH | 18.45 EUR |
Testo Thermometer 110+Battery - EACH |
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THE2070 | Scientific Laboratory Supplies | EACH | 163.04 EUR |
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THE1164 | Scientific Laboratory Supplies | EACH | 24.71 EUR |
Teflon Thermometer -10 to 210 - EACH |
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THE1166 | Scientific Laboratory Supplies | EACH | 30.11 EUR |
Teflon Thermometer -20 to 150 - EACH |
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THE1178 | Scientific Laboratory Supplies | EACH | 26.48 EUR |
Alarm Thermometer -50 to +150C - EACH |
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THE1502 | Scientific Laboratory Supplies | EACH | 39.15 EUR |
Digital Thermometer Hygrometer |
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Thermometer spirit-filled low temperat ure range -100 to 50 deg. c - EACH |
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Z257400-1EA | Scientific Laboratory Supplies | EACH | 51.17 EUR |
Spirit Thermometer -10 to 110C - EACH |
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THE1062 | Scientific Laboratory Supplies | EACH | 5.32 EUR |
Spirit Thermometer -10 to 150C - EACH |
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THE1064 | Scientific Laboratory Supplies | EACH | 4.41 EUR |
Spirit Thermometer -0 to 240F - EACH |
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THE1066 | Scientific Laboratory Supplies | EACH | 5.32 EUR |
Digital Thermometer -40 to 240 - EACH |
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THE1174 | Scientific Laboratory Supplies | EACH | 35.4 EUR |
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THE1176 | Scientific Laboratory Supplies | EACH | 67.12 EUR |