Evaluation of a Wearable Non-Invasive Thermometer for Monitoring Ear Canal Temperature during Physically Demanding (Outdoor) Work

The inclusion criterion was that the subjects should be physically active workers between 18 and 67 years of age (representing the European working population). The exclusion criteria included lung diseases, cardiovascular disease, claustrophobia, and problems associated with body heat loss (e.g., heat intolerance or difficulties with body thermoregulation resulting from sweating problems). The minimum sample size was calculated using a power analysis (non-inferiority trial with a power of 95%, significance level of 0.05, and acceptable difference of ±0.2 °C) for the laboratory study on the basis of the expected outcomes (n ≥ 11 subjects) and for the field study on the basis of the results of the laboratory study (n ≥ 26 subjects, with n ≥ 7 per job category).

The subjects of the laboratory (control) study were 15 volunteers (mean age: 25.1±4.2 years, nine males, six females) with no experience of wearing PPC or PPE, whereas the subjects of the field study were 49 physically active workers (mean age: 40.4 ± 10.2 years, 47 males, two females). All subjects were recruited by distributing flyers in selected companies with different working situations: (1) chemical cleaners working with chemical-proof PPC combined with other PPE; (2) mechanics working in a warm, humid factory; (3) firefighters working with PPC and PPE; and (4) neighborhood maintenance workers working outdoors in different weather conditions. The diversity in work-related tasks and working conditions between the subject groups, as specified, provided a broad picture of their influence on the accuracy and usability of the discussed wearable thermometer.

This study was performed in accordance with the Code of Ethics of the World Medical Association (Declaration of Helsinki) for experiments involving humans. This study was approved by the Medical Ethics Committee of University Medical Center Groningen, the Netherlands, stating that it does not involve medical research under Dutch law (laboratory study: M16.197311, field study: M17.209969). All subjects were informed of the study via an information letter and a verbal explanation before the start of the study, and all of them signed an informed consent form before participating in the study.

The in vitro accuracy of the Cosinuss° °Temp thermometer (aim 1) was examined in a thermostatic water bath. At a constant temperature, the temperature of the water bath was first measured with the Cosinuss° °Temp thermometer and a reference ear canal IR thermometer and compared to the results of the reference mercury thermometer. Then, the water temperature was increased from 35 °C to 41 °C in increments of 0.5 °C, and the temperature measured was checked against that of the mercury thermometer. Three measurements were performed at every step, with a frequency of one measurement per minute. The sensors were pointed downward in the water, with an angle of 90° between the sensor’s tip and the water surface. Before starting this laboratory study, the ear canal IR and mercury thermometers were (re)calibrated according to the national standard for medical thermometers (EN ISO 14971:2012, EN ISO 10993-1:2009, and EN 12470-5:2203).

To test the in vivo accuracy of the thermometer under controlled laboratory conditions (aim 2), the ear canal temperature (T_EC) of the subjects was measured at rest using the Cosinuss° °Temp thermometer and compared to the results obtained from the tympanic IR thermometer. The T_EC value was measured 10 times per subject with a frequency of one measurement per minute, yielding a 10 min measurement. All measurements were performed in offices with a constant room temperature of 20.0 ± 2.0 °C and 45.0 ± 5.0% humidity, and all subjects were allowed to acclimatize to this environment (for about 10 min; if necessary, every subject was allowed to have more time with a maximum of 15 min depending on their personal preference or if the T_EC value was not stable).

The field study was comprised of three stages: (1) accuracy measurements; (2) performance of daily jobs; and (3) accuracy measurements. To test the in vivo accuracy of the thermometer (aim 3), at stages 1 and 3, the T_EC value of the subjects was measured at rest using the Cosinuss° °Temp thermometer and a tympanic IR thermometer. In total, five measurements of T_EC were performed, with a frequency of one measurement per minute, yielding a 5-min measurement. In both the laboratory and field studies, ear canal thermometer positioning was monitored continuously and adjusted if needed.

To investigate the influence of real-life working conditions on the accuracy of the Cosinuss° °Temp thermometer (aim 4), during stage 2, the T_EC values and environmental conditions of the subjects were monitored while they were performing physically demanding work. All subjects performed their daily jobs while wearing the Cosinuss° °Temp thermometer, and the T_EC, T_cli, and RH values were continuously monitored using a wearable ambient conditions box. The duration of stage two depended on the duration of the subject’s task, lasting between 30 min and 3 h. When unrealistically high or low T_EC values were observed, the subjects were asked how they feel and whether they have any thermoregulation-related issues or health complaints.

During in vivo accuracy tests of aims 2, 3 and 4, the data gathered with the Cosinuss° °Temp were sent continuously to the ambient condition box via Bluetooth and stored every 1 s.

The usability of the Cosinuss° °Temp thermometer was explored (aim 5) using the AEIOU (Activities, Environments, Interactions, Objects, and Users) user interface design method via researchers’ observations and feedback from the subjects. In this descriptive observational study, the usability aspects were ease of use, positioning, wearability by all types of users, fixation, and comfort. In the laboratory study, subjects (Users) were asked to wear the Cosinuss° °Temp thermometer (Objects) while putting on and removing PPC (TRELLCHEM^® chemical-proof hazmat suit, Super type T; Ansell Protective Solutions AB, Trelleborg, Sweden) [43] with a separate gas mask during rest (3 min), while sitting (3 min), while walking (2 min), and while jumping (2 min) in PPC (Activities) for a total of 10 min. These two tests were performed directly after each other under constant ambient conditions (T_a = 20.0 ± 2.0 °C, RH = 45.0 ± 0.5%) (Environments). Under real-life working conditions (Environments), this was equivalent to the performance of daily jobs (Activities) in physically demanding occupations (Users).

To check whether the in vivo difference in the accuracy of the Cosinuss° °Temp thermometer compared to the IR thermometer was due to a misalignment in the ear canal caused by the thermometer’s positioning in the ear and/or individual differences (inner-ear dimensions), a correction factor was introduced. This individual correction factor was calculated using the second accuracy measurement (randomly chosen from the first five measurements out of 10 in the laboratory study and from the first three measurements out of five in the field study) during the in vivo measurements at rest. The T_EC value was measured using an IR thermometer in combination with a Cosinuss° °Temp thermometer in the other ear, and the difference between their measurements was used as the correction factor.

All statistical analyses were performed using IBM SPSS Statistics (version 25; IBM Corp., Armonk, NY, USA). To test the in vitro accuracy of the thermometer (aim 1), the mean of three measurements per step was used in the laboratory study. To statistically analyze the in vivo accuracy of the Cosinuss° °Temp thermometer (aim 2), every ninth measurement (out of 10) was used in the laboratory study and every fourth measurement (out of five) was used in the field study (aim 3). Differences were assessed using a paired t-test, and an intraclass correlation coefficient (ICC, two-way mixed model, absolute agreement) was calculated for normally distributed data. The ICC was considered low at <0.39, moderate at 0.40–0.59, high at 0.60–0.79, and very high at ≥0.80 [44]. Non-parametric data were also tested using Wilcoxon’s signed rank test. All p-values less than 0.05 were considered statistically significant. The limit of agreement (LoA) reflects the average difference between two different measurements and is calculated as ±1.96*SD difference [45]. For this study, the acceptable level for accuracy was set at mean difference (MD) ± 0.2 °C, with a moderate or (very) high ICC (≥0.40) and an LoA value of ≤0.50. Bland–Altman plots were created to analyze the individual differences between measurements against the individual mean of the two measurements. Generally, a funnel shape indicates that the magnitude of the difference is related to the mean performance. Sensitivity analyses were also performed to test the differences between the ninth and tenth measurements (laboratory study) and between the fourth and fifth measurements (field study), as well as for all the measurements. Descriptive statistics were used to analyze the usability in the laboratory and field studies (aims 3 and 5).

It was observed that the mean temperature difference in the thermostatic water bath between the mercury thermometer and the Cosinuss° °Temp thermometer was −0.4 ± 0.2 °C (MD ± SD; p < 0.001), whereas that between the mercury thermometer and IR thermometer was −0.2 ± 0.1 °C (p < 0.001). Table 1 shows the results of the ICC analysis for the three thermometers.

Table 1 shows a very high correlation between the Cosinuss° °Temp and IR thermometers compared to the mercury thermometer (ICC ≥ 0.97), with an LoA value of ≤0.37 (within the acceptable level of 0.50). Figure 3 shows Bland–Altman plots. Sensitivity analysis revealed non-significant differences.

It was observed that the mean T_EC value measured using the Cosinuss° °Temp thermometer was 35.2 ± 0.6 °C with a within-subject difference of 0.1 ± 0.1 °C. Table 2 shows the mean differences and results of the ICC analysis.

It was observed that the mean T_EC difference between the Cosinuss° °Temp thermometer and the IR thermometer exceeded the acceptable level (MD = −1.4 °C, p < 0.001) and exhibited a low correlation (ICC = 0.07, p = 0.083). However, after an individual correction factor (mean: 1.4 ± 0.6 °C, min: 0.7 °C, max: −2.5 °C) was applied, this mean difference decreased to an acceptable level (0.0 °C, p = 0.729) and a high correlation (ICC ≥ 0.72) was found. Figure 4 shows a Bland–Altman plot. Without correction, the Bland–Altmann plot showed bias between the mean differences; however, no funnel shape was visible. Sensitivity analysis revealed similar ICC and p-values.

In five subjects of the field study, the Cosinuss° °Temp thermometer stopped working because of the sweat that they produced while performing their jobs; the system was not fully waterproof, resulting in sweat on the electrical components (circuit board), corroding them over the course of the study. This resulted in loss of data and fewer results after work. Despite the incomplete datasets, all subjects were included in the accuracy study.

It was found that the mean T_EC of the Cosinuss° °Temp thermometer during the accuracy measurements was 35.0 ± 1.4 °C (mean ± SD) without correction. The mean correction factor was −1.7 ± 1.1 °C (min: 0.1 °C, max: −6.0 °C, outlier). Table 3 shows the mean differences and results of the ICC analysis for raw and corrected systems before and after work.

Before correction, an unacceptable high difference (MD = 1.5 °C, p < 0.001) and a low correlation (ICC ≤ 0.25, p ≤ 0.021) were observed, consistent with the laboratory study. However, after correction, the mean difference decreased to an acceptable level (MD = −0.2 °C, p ≤ 0.110) and the correlation between the Cosinuss° °Temp thermometer and IR thermometer became high. Before working an acceptable LoA value was observed (ICC = 0.77, p < 0.001, LoA = ±0.43). After the subjects performed their jobs, it was observed that the correlation between the Cosinuss° °Temp thermometer and IR thermometer decreased to a moderate level, exceeding the acceptable level of the LoA (ICC = 0.55, p < 0.001, LoA = ±1.90). Figure 5 shows Bland–Altman plots. Sensitivity analysis revealed similar results, with the sensitivity analysis of complete datasets only revealing non-significant differences.

While the workers were performing their jobs, it was observed that the mean T_EC was 36.8 ± 1.6 °C, with a mean T_cli value of 26.9 ± 4.9 °C and mean RH of 62.6 ± 12.7%. Table 4 shows the mean T_EC, T_cli, and RH measured using the Cosinuss° °Temp thermometer while the workers were performing their jobs. Each subject exhibited individual patterns of development of T_EC, with the micro-climate (T_cli) and RH differing from one job to another. Figure 6 shows the values of T_EC, T_cli, and RH over time while four representative individuals were performing their jobs. Table 4 andTable 5 outline the mean differences and results of the ICC analysis for the four different jobs mentioned earlier (with corrected Cosinuss° °Temp thermometer data; the raw Cosinuss° °Temp thermometer data are shown in Appendix A).

In the case of mechanics and neighborhood maintenance workers, it was observed that the working environment (i.e., temperature, RH) played a major role and influenced the development of T_EC, T_cli, and RH while they were performing their jobs. For mechanics, the values of T_cli and RH in the indoor working environment were constant within the subjects (see Figure 6, mechanics), resulting in a relatively constant T_EC. Before and after work, the mean difference was within the acceptable level (MD ≤ ±0.2, p ≥ 0.087) with a (very) high correlation (ICC ≥ 0.63, p ≤ 0.005). For neighborhood maintenance workers, it was observed that the outdoor working environment fluctuated, resulting in small fluctuations in T_EC (see Figure 6, neighborhood maintenance worker). Although the mean difference was within the acceptable level (MD ≤ ±0.2, p ≤ 0.796), the ICC value decreased from high (ICC = 0.67, p = 0.001) to negative, indicating a non-random effect influenced by a third variable [46]. For two mechanics and four neighborhood maintenance workers, the value of T_EC was lower than 35.0 °C. Given these results, the six subjects were asked how they felt, and all of them mentioned that they did not have any thermoregulation-related or health complaints. All six of them worked in cold, rainy/foggy, and/or windy environments, which implies that these measurement errors may have been due to the environmental conditions (e.g., wind or temperature of the working environment) [46].

In the case of chemical cleaners and firefighters, both the PPE (breathing apparatus) and chemical-proof PPC as well as the fire-proof PPC and helmet caused an increase in T_cli, RH, and T_EC as a result of transpiration and lack of ventilation. It was observed that when the PPC was removed after finishing the task, the values of T_cli and RH dropped rapidly, followed by the T_EC value (see Figure 6, firefighters). Before work, the firefighters showed a moderate correlation (ICC = 0.51, p < 0.001), which decreased to a low correlation after work (ICC = 0.28, p = 0.110). For chemical cleaners, this correlation remained high (ICC ≥ 0.60, p ≤ 0.029). While working, the T_EC value of nine subjects exceeded 40.0 °C, with abnormal values reaching a maximum T_EC of 46.4 ± 2.0 °C. These nine subjects comprised three chemical cleaners wearing PPC and PPE, four firefighters wearing PPC and PPE, and two neighborhood maintenance workers wearing temporary PPE (hearing protection). None of these subjects had any thermoregulation-related or health complaints, which implies that such an abnormal increase was due to them wearing PPC and PPE or due to environmental conditions. Sensitivity analysis (of complete datasets) revealed similar results or non-significant differences, and similar patterns were observed in all job types.

Generally, the Cosinuss° °Temp thermometer is easy to position in and around the ear. All subjects experienced a good fit with the Cosinuss° °Temp thermometer, and most of them reported it to be comfortable and to look professional. In the laboratory study, at rest, two subjects reported that the Cosinuss° °Temp thermometer felt loose and that they needed to reposition it by pushing it a little into their ears. It was reported that the thermometer remained in place during sitting, walking, and jumping in PPC. However, in all cases (n = 15), while the subjects were either wearing or taking off their chemical-proof suits, the thermometer fell out of their ears.

In real-life working conditions, all subjects reported that the Cosinuss° °Temp thermometer was non-obstructive and in general remained well fixated within their ears while they were performing their jobs. In two subjects, the thermometer fell out of the subjects’ ears while they were performing their jobs. In three subjects, the Cosinuss° °Temp thermometer felt loosely fixated within the ear and was repositioned by the subject. In eight subjects (seven chemical cleaners, one firefighter), the thermometer fell out of their ears while they were taking off their PPC, helmets, or head-related parts of their chemical-proof suits. Figure 6 shows how the falling of the thermometer out of the ear reflects in a drop of T_EC (see Figure 6, chemical cleaners). Importantly, the Cosinuss° °Temp thermometer did not interfere with task performance. Although the firefighters mentioned that there may be some complications for workers who need to wear in-ear hearing protection equipment or an in-ear communication device.