1. Introduction
Ever-growing technological development is offering new solutions to monitor athletes and exercise practitioners with wearable sensors in applied settings. The physiological and mechanical variables currently available may help refine the prescription and monitoring of training and assess its effects, with potential benefits for the health and exercise performance of different populations. One of the physiological variables that is gaining particular interest in the exercise community is respiratory frequency (
fR) [
1,
2], also considering the numerous techniques suitable for its measure [
3,
4]. Unlike other physiological variables (including tidal volume, V
T),
fR is closely associated with perceived exertion [
5,
6,
7,
8,
9], and its time course reflects changes in exercise tolerance [
10]. The fact that the depth (i.e., V
T) and rate (i.e.,
fR) of breathing provide different information is supported by their differential control, as V
T and
fR are mainly modulated by metabolic and non-metabolic inputs, respectively [
8,
10,
11,
12]. As such,
fR has been defined as the behavioral component of minute ventilation [
1,
10].
The notion that
fR is a valid marker of physical effort, especially at high intensities, is particularly evident during cycling exercise and applies to a variety of exercise paradigms, including incremental exercise [
13], time trial [
6,
8,
14], time to exhaustion [
5], trapezoidal exercise [
11], all-out exercise [
15], and high-intensity interval training (HIIT) [
8,
14,
16]. HIIT shows a feature of
fR that distinguishes the behavioral component of minute ventilation from commonly monitored physiological variables such as oxygen uptake, heart rate, and blood lactate. Indeed,
fR responds rapidly to the alternation of work and recovery, while the other variables show a delayed response both at the onset and offset of the work phase [
8,
16,
17,
18]. This offers an advantage in monitoring cycling exercise as well as other sports that are characterized by intermittent activities [
1,
7].
While the measurement of
fR and other ventilatory variables has a long tradition in exercise physiology laboratories, interest in custom-made and commercial wearable devices suitable for
fR monitoring in applied exercise settings has increased substantially in recent years [
1,
2]. Different methods can be used to monitor
fR in applied exercise settings, and some of them are attracting particular attention, including the techniques recording chest wall movements and those extracting
fR from physiological signals modulated by breathing (e.g., the electrocardiographic signal). Among the sensors recording chest wall movements, those measuring strain can be easily integrated into clothes or textiles, which facilitates the development of unobtrusive devices. Different wearables integrating strain sensors have been developed and tested during exercise, generally showing a relatively good performance in measuring
fR [
19,
20,
21,
22,
23,
24,
25,
26,
27]. The other emerging trend in the field of exercise is the attempt to extract
fR from cardiac signals registered from heart rate straps or other devices, where the main advantage is that these signals are already recorded by many athletes and exercise practitioners [
28,
29]. However, the error in estimating
fR from cardiac signals is usually higher than that found when strain sensors are used [
28,
29]. A common problem of the aforementioned techniques is that the registered respiratory signal is susceptible to motion artefacts, which implies that the evaluation of the validity of
fR measurement should be sport specific. Indeed, motion artefacts may affect the quality of the respiratory signal more in some sports (e.g., running) than others (e.g., cycling). However, even in cycling, some exercise paradigms may challenge the quality of the respiratory signal. For instance, we found that the error in measuring
fR was higher during HIIT compared to incremental exercise, even when the signal was recorded with a differential pressure sensor and was thus minimally affected by motion artefacts [
30]. Hence, the use of HIIT in validation studies is encouraged but currently underappreciated. Another important overlooked requirement of validation studies is the need to assess the quality of the respiratory signal at a breath-by-breath level because different respiratory services may need such a level of detail (e.g., real-time monitoring) [
1,
30]. The quality of validation studies performed during exercise should improve accordingly.
The variety of sensors available for measuring
fR allows for the identification of other wearable solutions that have so far been considered to a limited extent and may partially solve some of the above-mentioned problems. We have recently started exploiting the very good metrological characteristics of some temperature sensors recording a respiratory waveform that is minimally affected by motion artefacts [
31]. This feature of temperature sensors has long been appreciated in the field of exercise physiology, where thermistors or thermocouples have been used for the assessment of the locomotor-respiratory coupling phenomenon [
32,
33,
34,
35,
36,
37], which requires a very good signal quality for its detection. However, the characteristics of temperature sensors have rarely been exploited for the development of wearable sensors suitable for exercise monitoring, which is currently facilitated by the miniaturization of electronics. In a first attempt, we located a thermistor embedded into a small electronic board close to the orifice of a face mask used for laboratory exercise testing, and we found relatively low errors in measuring
fR [
31]. However, this preliminary solution was still far from the usability requirements needed for exercise monitoring in applied settings. Hence, in this study, we present the design and testing of a new solution exploiting the use of a temperature biosensor located in a facemask for
fR monitoring during cycling exercise.
2. Smart Facemask: Design and Description
The smart device presented in this paper has been designed from both a hardware and software perspective to meet the requirements of
fR monitoring during cycling exercise without restricting the athlete’s mobility or influencing the proper execution of exercise sessions. Hence, in the design and development of the smart device, we considered the following requirements: (i) keep the weight and dimensions as low as possible; (ii) guarantee the washability of components in contact with the athlete after use, to have the correct level of hygiene; (iii) guarantee the continuous data acquisition for more than 10 h, which is a duration that largely exceeds the usual requirements of elite cyclists [
38]; (iv) ensure low air resistance to the athlete’s respiratory flow; (v) ensure low motion artefacts sensitivity.
To fulfil all the requirements, the system’s design was intended to avoid any sensing element in contact with the subject and to maximize the sensitivity to respiratory activity while minimizing the influence of motion artefacts. We decided to develop a smart facemask with a modular architecture that consists of four main units: (i)
central data logger: designed for data acquisition, digitalization, and transmission; (ii)
remote base station: designed for sending data messages to the central data logger and to store the raw sensor data; (iii)
sensor unit: designed to be the sensing part of the whole system; (iv)
case unit: designed to fit the subject’s face and to integrate both the central data logger and the sensor unit. An example of all the main units and their modules is shown in
Figure 1.
The characteristics of the four main units of our system are as follows:
(1) The sensor unit includes three modules: (i) a breathing module that uses an NTC Radial Glass Thermistor (model number: G10K3976B1, TE connectivity, Resistance and Tolerance @ +25 °C: 10 kΩ and 1%; time response in stirred oil: 0.4 s; Beta Value 25/85: 3976 K) and a voltage divider with a fixed resistance of 10 kΩ. The glass body of the selected thermistor provides a hermetic seal and voltage insulation; hence it can operate in high temperature and moisture environments. This module was designed to monitor respiratory activity by collecting the temperature of the airflow exhaled by the nose and mouth (i.e., TExp); (ii) a motion module that consists of a triaxial accelerometer (model Bosch® BMI160) with ±16 g scale. This module was added to provide an estimation of exercise-induced head accelerations that may provide information on the athlete’s movement (e.g., pedalling cadence); (iii) an external temperature module that consists of a surface-mount temperature sensor (model number NCP15XH103F03RC, accuracy ±5 °C) positioned so as not to be hit by the flow of air exhaled by the subject. This module was selected to collect the external temperature (i.e., system’s working temperature, henceforth TE).
(2) The central data logger consists of a small (diameter: 24 mm, height: 6 mm) and low-weight (56.7 g) electronic board that integrates a Bluetooth low energy (BLE) module (Bluetooth LE 4.2–2.4 GHz), the motion module and the external temperature module. In addition, it has four general-purpose I/O (GPIO) ports, a power supply port (3 V), and a 10-bit analog to digital converter (ADC). One of the GPIOs houses the breathing module that is also supplied by the power supply port. The analog-acquired signal is then sent to a 10-bit ADC in the acquisition board for digitalization. This module allows us to receive data messages from the remote base station. The central data logger is supplied by an interchangeable lithium coin cell (capacity up to 240 mA/h, 20–54 °C) that guarantees more than 700 h of continuous acquisition, widely sufficient for a typical training session.
(3) The remote base station consists of a Raspberry Pi that allows sending data messages in a Python environment to the central data logger to provide instructions to (i) set the sampling frequency of each sensor unit (i.e., 50 Hz for the breathing and motion modules; 1 Hz for the external temperature module) and start the data recording inside the central data logger internal memory (8 MB); (ii) stop the data acquisition; (iii) begin the data download; (iv) retry the connection during the download in the case of connection drops. Additionally, it allows us to store the raw sensor data in a csv format when sent from the central data logger via BLE.
(4) The
case unit was designed with two detachable modules. The first module is called the
pull-out module and is made up of a housing for the sensor unit and a housing for the central data logger, as shown in
Figure 1. This is made up of 3D-printed polylactic acid with a Creality Ender-3 v2 in the shape of a ‘spoon’ with an overall weight of 7 g. The design was intended so that most of the nose and mouth airflow hits the tip of the thermistor (approximately 2 cm away from the tip of the mouth) of the breathing module, which emerges from the concave side of the spoon (see
Figure 1). This configuration makes it possible to record temperature changes during the inspiratory and expiratory phases of breathing. On the other hand, the ‘spoon’ was specifically designed to make the thermistor unexposed to wind. At the top of the ‘spoon’, we designed housing for the central data logger positioned in the central part of the subject’s head to obtain a more reliable signal of the head’s accelerations from the motion module. The second module of the case unit is called the
core module and was realized to be completely electronics-free. It is a facemask made from 3D-printed Thermoplastic Polyurethane 95A, with an overall weight of 45 g. This module was designed to accommodate the pull-out module so that the latter can be hooked during the test and unhooked when the facemask is washed and sanitized. It also has a 40 mm diameter hole in the front to ensure low air resistance to the athlete’s airflow. This prevents the proposed mask from forming a closed space around the nose and mouth once fitted. Finally, it has four housings for the headband that can be worn and set by the athlete so that the facemask properly fits the face.
In this paper, we will focus mainly on the breathing module of the sensor unit (see
Figure 1) and its performance. The system’s working principle, the developed algorithm for respiratory analysis, preliminary tests, and the validation process conducted against a reference flowmeter on athletes are presented below.
3. System’s Principle of Working and fR Estimation: Algorithm Design
The operating principle of our system for collecting respiratory biosignals is based on variations in the air temperature flowing out of the nose and mouth during the breathing activity to which it is exposed. Our sensor has a variable resistance (R) as the temperature (T) varies with a negative transformation coefficient. Therefore, when the T increases, the R decreases. In the absence of exhaled airflow (e.g., sensor not worn by the subject or during apnea), the respiratory module is surrounded by T
E, so the output temperature signal (and the resistance signal) remains stable. On the other hand, during exhalation, the airflow impinges on the respiratory module at a temperature (T
Exp) of approximately 37 °C [
39]. Thus, the behavior of the biosensor is as follows:
Instead, in the inhalation phase, the respiratory module sensor is re-exposed to TE. Therefore, the phenomenon is ‘passive’ and behaves as follows:
To extract
fR from the collected respiratory signals
, two different algorithms were implemented, as shown in
Figure 3. The first algorithm was used to extract the breath-by-breath
fR, while the second algorithm was used to extract the average
fR in 30 s windows. In both algorithms, the breathing signal was filtered with a Butterworth band-pass filter (BPF) with cut frequencies of 0.01 Hz and 2 Hz to obtain
[
1,
40,
41]. Hence, the components of physiological breathing frequency values are preserved in the signal.
Subsequently, with Algorithm#1, the
fR was directly extracted from the
. For this purpose, the peaks corresponding to the end of exhalation were selected with an algorithm based on both temporal and amplitude criteria to exclude artefacts. The temporal criterion states that two consecutive peaks are selected as separate events if their distance exceeds a minimum value set at 0.6 s because, even during maximal effort exercise, the
fR of human adults usually remains below 1.67 Hz (100 breaths/min) except for extreme exercise conditions [
15]. Regarding the amplitude criterion, we set a percentage threshold of 2% of the maximum peak-to-peak amplitude of the signal in order to be robust to changes in signal amplitude. Only peaks exceeding this threshold were selected as breathing events, while the others were discarded. The distance between two different breathing cycles (
) was calculated as the elapsed time between two consecutive breathing events. Consequently, the breath-by-breath
fR (i.e.,
) was calculated as 60/
.
Algorithm#2 employs the previously described algorithm (Algorithm#1) within 30 s windows. Thus, in each window, the breath-by-breath fR (i.e., ) was computed, and the average one was calculated (e.g., in the w-th window). This resulted in an average value for each window.
4. In-Lab Tests with the Mechanical Ventilator: Description and Results
To assess the feasibility of the smart facemask in monitoring
fR, preliminary tests were conducted in the laboratory. The aim of this preliminary analysis is to investigate the behavior of the entire system when it is provided with simulated respiratory flows at set frequencies ranging from 5 to 75 bpm. For this purpose, we used an experimental setup consisting of (i) a mechanical ventilator (SERVO VENTILATOR 300, SIEMENS,
fR accuracy ±1 bpm or 10% of the set value) used to provide frequency-controlled air flows; (ii) a humidifier (MR850ALU, Fisher&Paykel HEALTHCARE) used to heat and humidify the air coming out of the mechanical ventilator; (iii) a 3D-printed Polylactic Acid PLA box containing the smart facemask. This box is designed with a front hole to convey the airflow onto the breathing module and a rear hole that allows the airflow to pass through, minimizing losses; (iv) a coolant box that aims to keep the T
E outside the facemask almost constant at ~25 °C; (v) a lung simulator that aims to simulate the adult’s respiratory airways. Thus, the airflow originating from the mechanical ventilator passes through the humidifier to be heated and humidified (temperature 37 °C, relative humidity 100%). The heated and humidified flow is directed into the PLA box through a corrugated tube connected to the front hole and impinges on the thermistor of the respiratory module of the smart facemask. Subsequently, the flow exits through the rear hole and reaches the test lung simulator, which captures the flow and then returns it to the mechanical ventilator. An example of the whole system is shown in
Figure 4.
Experiments were conducted to simulate eight different
fR levels. The set
fR ranged from 5 bpm to 75 bpm in steps of 10 bpm to investigate the typical frequencies of a subject at rest and during exercise [
1]. For each set
fR, 10 respiratory acts were simulated.
To evaluate the performance of the developed device, the breath-by-breath
fR was extracted from the respiratory module signal with Algorithm#1 and compared to the frequency values set on the mechanical ventilator. For each set
fR, the measured values were reported as shown in Equation (1):
where
denotes the mean of the measurements and
is the uncertainty calculated using Student’s distribution and expressed as follows in Equation (2):
where
k is equal to 2.306 and denotes the coverage factor considering a 95% confidence level,
is the standard deviation of the measurements, and
N is the number of the extracted
fR values (i.e., 9). The deviation obtained by comparing the values measured with the developed system and those set on the mechanical ventilator is shown in
Figure 5.
We examined the discrepancy between the measurements provided by the two instruments, defined as the difference between two measured values of the same quantity with both the device and the reference system. Hence, we assessed whether there were any points in common between the interval
and the interval
.
Figure 5 shows that there is no discrepancy between the two measurements for all the tested
fR. Additionally, the results exhibit an average error of less than 0.6 bpm with a maximum deviation of the mean values of 0.58 bpm for a set frequency of 15 bpm and an overall overestimation of the proposed system with respect to the reference in all but two set frequencies (i.e., 35 and 65 bpm).
5. Validation of the Smart Facemask and Algorithms: Experimental Tests on Athletes
Experimental tests were carried out to validate the proposed smart facemask against a reference instrument for fR monitoring and pedalling cadence estimation.
(1) Population, Experimental Setup, and Protocol: Ten trained healthy non-smoker cyclists (10 males, mean ± SD: age 25 ± 6 years, body mass 68 ± 6 kg, height 174 ± 5 cm) were enrolled for this purpose. The study was approved by the Institutional Review Board of the University of Rome “Foro Italico” (CAR 112/2021). The principles of the Declaration of Helsinki were followed in all steps of the study, and written informed consent for study participation was signed by all volunteers. To validate the proposed device, we conducted an indoor testing session at TE of about 26 °C (obtained by averaging all the recorded TE during the indoor tests). A gold-standard flowmeter (Quark PFT, COSMED S.r.l., Rome, Italy) was used to collect reference respiratory airflow () at 50 Hz.
Before starting the test, each volunteer was asked to wear the developed smart facemask with a properly adjusted headband to keep it fixed on the face. The flowmeter was placed in a dedicated hole realized on the core module of the smart facemask. The test was performed on a cycle-ergometer (WattBike Pro, model WAT-1W51-015-15) that was set for each participant based on comfort and anthropometric characteristics. After an initial familiarization phase and a 3 min warm-up, participants were encouraged to perform a starting sequence consisting of three deep breaths followed by apnea. This procedure was used to synchronize the respiratory signals collected with the smart facemask and the reference system. Then, they were asked to complete two different exercise protocols interspersed by 3 min of recovery (see
Figure 6A):
Ramp incremental respiratory frequency test (henceforth referred to as RIFT), where participants were asked to replace spontaneous breathing with the
fR paced by a metronome. This test lasted 5 min, and the
fR paced by the metronome increased from 20 bpm to 75 bpm in an exponential fashion. Participants were asked to cycle during this test and to self-select pedalling cadence and power output according to preference. The execution of this test has several advantages: (i) the time course of
fR resembles the response commonly observed during incremental exercise [
10,
42]; (ii) the range of
fR values exceeds the range of values commonly observed during cycling exercise [
1,
6,
14]; (iii) it allows for the evaluation of the quality of the respiratory signal even when no reference system is used (see
Section 6 Outdoor Tests).
High-intensity interval training (henceforth referred to as HIIT) test composed of eight repetitions of 20 s of work and 40 s of recovery. The work-phase power output was self-selected by the cyclist to reach approximately a value of 19 of the Borg’s 6–20 ratings of perceived exertion scale [
43] on the last of the eight repetitions.
5.1. Breathing Module for fR Monitoring
Prior to data analysis, all the signals recorded with the facemask (T
Exp signal, T
E signal, motion module signal) were synchronized with the
ϕ reference signal starting from the third deep breath of the starting sequence. The reference
ϕ provides a pseudo-periodic signal with a negative phase corresponding to inspiration and a positive phase corresponding to expiration (see
Figure 2C);
ϕ signal was integrated to obtain a volume signal (V), in accordance with previous studies [
44,
45]. V has an increasing trend during exhalation and a decreasing trend during inhalation, comparable to the signal acquired with our device. Algorithm#1 and Algorithm#2 were applied to T
Exp and V to estimate the
(breath-by-breath
) and
(average
in 30 s-windows), respectively.
For both algorithms, comparison between data provided by the developed system and those from the reference device was performed using the Bland-Altman analysis [
46]. The latter was carried out to assess bias between the two measurement systems and expressed in terms of the mean of differences (MOD) and limits of agreement (LOAs), calculated as 1.96 times the standard deviation of the differences between the
values estimated by the two methods.
In addition, the following statistical indexes were calculated: the mean absolute error (MAE) and the mean absolute percentage error (MAPE), respectively, defined as in Equations (3) and (4):
where
N represents the number of breaths extracted or the number of windows when using Algorithm#1 or Algorithm#2, respectively.
Table 1A,B shows the number of breaths extracted using Algorithm#1, the MOD ± LOAs from the Bland–Altman analysis, and the MAE and MAPE values calculated for the RIFT test and HIIT test, respectively.
Table 2A,B shows the results of the 30 s-window analysis extracted using Algorithm#2 and the number of windows in which the signals were windowed.
For the sake of clarity, the graphs of the Bland–Altman analysis performed for both the HIIT and RIFT test by all subjects in the indoor test are shown below (see
Figure 7).
5.2. Motion Module for Cadence Estimation
The motion module placed on the smart facemask was used to assess the ability to estimate the cycling cadence from the accelerations at the level of the head when compared to the cycling cadence extracted from the cycle-ergometer. The idea is that the y-axis (i.e., lateral axis as in
Figure 1) of the accelerometer has a cyclical pattern at a frequency resembling that of cycling with a peak local maximum for each pedal stroke of the same foot (defined as an event). Indeed, it is conceivable that the cyclist tends to slightly move his head according to changes in weight distribution during pedalling.
The y-axis accelerations of the motion module were analyzed in the MATLAB environment. Data collected with the cycle-ergometer (reference cadence values) and the motion module were synchronized and split into RIFT traces and HIIT traces. Then, two main steps were performed on the motion module signal to extract the cycling cadence:
- -
Signal filtering;
- -
Event-by-event extraction in the time domain.
The signal filtering stage involves the implementation of a first-order BPF with a lower cut-off frequency of 0.01 Hz and a higher cut-off frequency of 3 Hz to better emphasize the contribution of head movement due to the cycling activity. The event-by-event extraction in the time domain consists of selecting the maximum peaks in the signal and computing their distance in time. This corresponds to the period (i.e., ) between a head movement between one pedalling cycle and the following one. We then computed the cycling cadence as expressed in revolutions per minute (rpm). Finally, we applied a Hampel filter to detect and remove outliers, defined as the samples that differ from the median by more than three standard deviations.
Cadence values extracted from the motion module were then compared with those extracted from the cycle-ergometer, used as reference ones. To compare the results, the cadence values extracted from the reference cycle-ergometer and our device were resampled at 1 Hz to have one cadence value per second for both devices. A graphical comparison between the cadence values extracted from the two devices for all subjects is shown in
Figure 8. In addition, the MAE value for each subject was calculated as shown in Equation (3).
6. Outdoor Tests
On a subset of the participants (six), we carried out a second testing session to assess the feasibility of using our system in an outdoor setting with an external temperature (T
E) higher than 32 °C, and thus closer to T
Exp compared to the indoor setting (see
Figure 6B). No reference system was used in these tests performed outdoors because the stationary metabolic cart we used could not be transported outside the laboratory. However, this limitation did not prevent us from testing the feasibility of measuring
fR with the smart facemask, as detailed below.
To investigate the influence of T
E on the facemask output signal, we first assessed the amplitude of the signal (A) recorded indoors and outdoors during the RIFT. Per each trial, A was calculated as in the following formula:
where
. and
are the maximum (red triangles in
Figure 9) and minimum (green triangles) voltage values of the
i-th breath, respectively.
Figure 9 shows the amplitude of the data collected from one volunteer during indoor and outdoor tests.
Table 3 reports the average and standard deviation values of the temperature (T
average) extracted from the T
E signal and the A values for both the indoor and outdoor tests. Despite the A being substantially higher in the indoor test than in the outdoor test, the quality of the temperature respiratory signal was preserved even in the outdoor setting, as shown in
Figure 9.
Given the absence of the reference system in the outdoor test, a further assessment of the quality of the temperature signal was made by evaluating the
fR response during RIFT, where participants were asked to follow the
fR paced by a metronome. Since participants may commit errors when attempting to follow the pace set by the metronome, we considered this error by calculating an index estimating the ability of the athlete to perform the breathing task. This was made by means of the RMSE value, which was computed during the indoor test, where both the reference signal ϕ and the temperature respiratory signal T
exp were recorded. Specifically, we calculated two RMSE values per each volunteer: the first considering the
fR values provided by the reference system vs. the
fR values imposed by the metronome, and the second considering the
fR values provided by the facemask vs. the
fR values imposed by the metronome. Very similar RMSE values were observed for the facemask and the reference system (see
Figure 10A), which outlines that the between-participant differences in RMSE observed were mainly due to errors committed when performing the breathing task rather than representing measurement errors of the facemask. This consideration is important for a correct interpretation of the RIFT data collected in the outdoor setting.
The RMSE value of data collected during the outdoor test was then calculated for each participant using the
fR values provided by the smart facemask (blue line,
Figure 10B) vs. the
fR values imposed by the metronome (red line). Similar RMSE values were generally found for the same participant in the indoor and outdoor tests, which further suggests that the small discrepancy observed between the
fR values of the facemask and those set by the metronome was largely due to errors made by the participants when performing the breathing task. Notably, even without deducting the error made by participants from the RMSE computation, the
fR response observed during RIFT closely resembled the
fR time course set by the metronome, as depicted in
Figure 10 and
Figure 11. The
fR time course observed during HIIT both during indoor and outdoor tests (see
Figure 11) further supports the quality of the data collected from the smart facemask, as the observed response is in line with the response reported in the literature during similar HIIT tests performed in the cycling modality [
2,
8,
16].
7. Discussions
The purpose of this study was to test the validity of a wearable smart facemask measuring
fR during cycling exercise. The custom-made system was developed to suit the requirements of athletes and exercise practitioners, both in terms of wearability and quality of the respiratory signal. When compared to the reference system, we found a very good performance of the smart facemask in measuring
fR, both during progressive increases in
fR paced by a metronome and during HIIT. Precision and accuracy were very good, and the MAE was always lower than 2 bpm, even when the validity of the
fR measurement was assessed at a breath-by-breath level. Moreover, when the validity was assessed on
fR values averaged every 30 s, the MAPE was always lower than 1%. We found that the quality of the respiratory temperature signal was preserved even when tests were performed outdoors at temperatures above 30 °C, despite a substantial reduction in the amplitude of the signal. Both the indoor and outdoor HIIT tests showed the characteristic fast response of
fR to the alternation of work and recovery (see
Figure 11), which makes
fR particularly suitable for monitoring high-intensity exercise [
2,
7,
8,
16]. These findings have important implications for both research and exercise management in different populations.
The very low errors found for the proposed facemask have rarely been reported when testing the validity of other wearable devices during exercise. Not only is our solution superior to recent attempts made in extracting
fR from cardiac signals [
28,
29], but it also appears to overperform commercial and custom-made wearable devices integrating strain sensors. For instance, substantially higher error values than those observed in our study were found when assessing the validity of the Zephyr
TM BioHarness
TM chest strap of the Hexoskin
® smart shirt and of the capaciflector sensors tested by Hayward et al. [
19,
20,
23,
24,
25,
26]. Notably, the performance of our facemask is even superior to that of a custom-made wearable device integrating a differential pressure sensor previously tested in similar exercise conditions and using similar analyses [
30]. During HIIT, the previous study found average MAPE values of 4.03% and 1.77% when computed breath-by-breath or on 30 s windows, respectively [
30], while we found average values of 1.64% and 0.23%, respectively, in this study. The very good performance of our smart facemask is not surprising if we consider that the good quality of the respiratory temperature signal has long been exploited in the field of exercise physiology for the evaluation of the locomotor-respiratory coupling phenomenon [
32,
33,
34,
35,
36,
37]. Indeed, its assessment requires the accurate measurement of
fR and its subcomponents at a breath-by-breath level. However, the good metrological characteristics of the temperature sensors have not so far been effectively used for developing wearable sensors measuring
fR during exercise, and our study makes an important step in this direction.
The performance of the smart facemask presented herein is substantially better than that of a preliminary system that we tested in our laboratory [
31], and several factors explain the improvements made in the quality of the temperature respiratory signal. The preliminary system had a temperature sensor embedded into the electronic board and had thus been located outside of a commercial facemask used for exercise testing. That system was prone to artefacts caused by wind and had only been preliminarily tested in the laboratory [
31]. Conversely, the herein-presented smart facemask was developed with account taken of the needs of both indoor and outdoor exercise testing. Hence, the temperature sensor was not embedded into the electronic board but was conveniently located in the facemask and integrated into a spoon-shaped housing system allowing the sensor to be directly exposed to nose and mouth airflow and unexposed to wind. As a result, our smart facemask resulted in about 2–4 times lower MAPE values compared to the previously tested preliminary system [
31].
Before discussing the important implications of our findings, we acknowledge the limitation of monitoring exercise with a facemask, albeit wearable and light, as this prevents the possibility for athletes and exercise practitioners from wearing it daily. Indeed, the devices that athletes commonly wear on a daily basis are less obtrusive (e.g., heart rate straps, global positioning systems, etc.). On the other hand, the assessment of athletes’ ventilatory responses has so far been performed with devices requiring the use of a facemask (mostly in the laboratory), and hence athletes are used to wearing a facemask for exercise testing. Our smart facemask may play an important role in the attempt to move respiratory monitoring from the laboratory to the field. Indeed, not all the attempts made so far by companies or researchers to use unobtrusive wearable devices for measuring
fR have resulted in valuable information provided to the athlete or the exercise practitioner. For instance, when using some analyses/sensors for processing/recording the cardiac signal to extract
fR [
28,
29], the
fR measurement error may not be negligible. In fact, this issue may also apply to a variety of other sensors and devices because it is common practice to perform validation studies in the laboratory and assume that the devices under validation would exhibit similar performance in the field. However, some researchers have encouraged the verification of this assumption because different exercise protocols, modalities, and environmental factors may affect the quality of the respiratory signal [
28,
29]. Hence, our facemask meets the current need of the sports science community to have a wearable, light, affordable, accurate, and precise device that can be used to test the validity of
fR measurements made by other wearable devices in the field. This implies that our facemask can also be used for applied research performed in the field, thus facilitating our understanding of how
fR responds and is regulated in applied exercise settings.
In an attempt to extract valuable information from the
fR response, it is important to monitor other variables to understand the context leading to the observed response. The movement module of the smart facemask is not only suitable for recognizing if the user is cycling or not, but it also appears to provide pedalling cadence values with relatively low errors. Indeed, we observed MAE values always lower than 4 rpm even during HIIT (the values ranged from 1.9 to 3.9 rpm), where pedalling cadence values higher than 100 rpm were found in all the participants. This is important because pedalling cadence affects
fR, although we have found that
fR does not change in proportion to pedalling cadence as this relationship is moderated by exercise intensity [
47]. Indeed, it is more likely to observe consistent changes in pedalling cadence and
fR during low-to-moderate exercise than during high-intensity exercise [
47]. Nevertheless, the fact that pedalling cadence may confound the association between
fR and perceived exertion (especially at low intensities) [
47] outlines the need to measure pedalling cadence alongside
fR, and our smart facemask appears to be suitable for this purpose.
While we do not advise the use of the herein-presented facemask for monitoring athletes on a daily basis, the device can be used for a variety of other applications requiring accurate
fR measurements. Performance assessment is fundamental for managing the training process, and our device is suitable for use during both maximal and submaximal tests [
31]. Indeed, the fact that the
fR time course is sensitive to changes in exercise capacity makes respiratory monitoring suitable for gaining insights into performance adaptations [
10]. There is also an emerging interest in the voluntary modulation of the breathing pattern during exercise [
48]. Although further research is needed before any suggestion can be made on the acute or chronic use of breathing strategies during exercise, our smart facemask may support research in this area and facilitate the practice of breathing strategies. Furthermore, the accurate measurement of
fR has the potential to refine exercise prescription and monitoring in patients. Indeed, all the patients experiencing a reduction in exercise capacity, not only the patients affected by pulmonary diseases, have an anticipated increase in
fR compared to healthy individuals [
10], and the sensitivity of
fR to changes in exercise tolerance may prove useful for monitoring patients.
While the characteristics of our smart facemask make it suitable for
fR monitoring in a variety of sporting activities and populations, our findings may not be generalized to conditions different from those tested in the present study until further research is performed. For instance, we have not tested female participants, although there is no reason to assume that the temperature respiratory waveform is substantially different between males and females. Hence, while gender differences should be considered when assessing wearable devices recording respiratory-induced movements, this issue is negligible for devices measuring airflow temperature. Unlike the respiratory waveform recorded with strain sensors, the temperature respiratory waveform is neither substantially affected by interindividual differences in anthropometric characteristics nor movement artefacts, and this contributes to explaining why we found similar errors of measurement between different participants. This suggests that our findings can be generalized to healthy, trained male individuals performing cycling exercise despite the relatively low sample size tested. On the other hand, we cannot exclude that the use of a facemask may affect the breathing pattern, and interest in this issue has been further stimulated by recent research exploring the physiological effects of the protective masks used for contrasting the spread of the COVID-19 virus. The systematic review by Zheng et al. [
49] suggests that the use of facemasks during exercise does not substantially affect
fR, which encourages the use of our facemask that was specifically designed to minimize respiratory resistance while making the temperature sensor unexposed to wind. However, further research is required to specifically test the effects of our facemask on
fR and exercise performance.