2.1

Development of the wireless device

The wireless device ( Fig. 1 a) included a power supply printed circuit board (PCB; L ÿ W ÿ H: 14.0 ÿ 10.0 ÿ 0.8 mm) and a main PCB (L ÿ W ÿ H: 16.0 ÿ 10.5 ÿ 0.8 mm; Kamahi Electronics, Dunedin, New Zealand). The power supply PCB hosted a lithium magnesium di-oxide battery (CR1025, Renata, Switzerland), which provided sufficient power to collect data for >2 weeks. The main PCB included: an amplifier (Zerø-Crossover Rail-to-rail I/O operational amplifier, Texas Instruments, Dallas, Texas, USA); a microcontroller (PIC16FLF1825, Microchip Technology Incorporation, USA); a linear active thermistor (MCP9700AT, Microchip Technology Incorporation, Minnesota, USA); and an ANT ⁺ ultra-low power single chip (NRF24AP2, Dynastream Innovation, Trondheim, Norway). The pH and temperature measurements were transmitted to an ANT ⁺ -supported smartphone (Xperia M2, Sony, Tokyo, Japan) once every two seconds (0.5 Hz) using the Industrial, Scientific and Medical band (2.4 GHz). During each transmission, the radiofrequency transmitter only operated for 0.2 ms and otherwise remained off. This device fully complies with the New Zealand Standard for radiofrequency field exposure NZS 2772.1-1999. A small (ÿ = 2.4 mm) pH antimony electrode (Primus, Restech, San Diego, California, USA) was connected to the main PCB. The antimony electrode detects pH in aerosolised droplets without requiring full immersion or contact with fluid for electrical continuity .

Example of a fully assembled wireless device. a) The tip of antimony electrode (see arrow) is attached to the main printed circuit board (left hand side). b) wireless unit embedded in a vacuum-formed splint, with the antimony electrode tip (see arrow) positioned close to the palatal surface of the upper central incisors.

2.2

Software application

An Android software application was developed for the calibration, monitoring and recording of pH and temperature by the smart phone. The application was designed to be user-friendly, showing real-time dynamic charts of pH and temperature values (Appendix B). The graphing library ⿿achartengine⿿ ( www.achartengine.org ) was used to create the graphs. On-phone calibration was based on the standard two-point temperature and pH calibration process. The application saved individual log files for each recording session, which included basic demographic data.

2.3

Device testing and validation

In vitro experiments were conducted to test the accuracy and precision of the device. These experiments were conducted with the wireless unit not incorporated in an oral appliance. The accuracy of the thermistor was tested against a laboratory thermometer (Brannan thermometers, Cleator Moor, Cumbria, England), while heating the wireless unit with a laboratory incubator (Laboratory equipment Ptw, Marrickville, New South Wales, Australia).

The effect of temperature on the antimony pH electrode was tested using pH 7.4 phosphate buffered saline solution (Sigma-Aldrich ^® , St. Louis, Missouri, USA), in water baths set at 25, 35, or 45 ° C. The reading stability was tested by continuously measuring pH with the antimony electrode at a constant temperature (23.5 ° C) and pH (7.0) for 24 h.

The accuracy of the antimony electrode was tested against a standard glass pH electrode (PL-700 PVS, GOnDO Electronic, Taipei, Taiwan). The antimony and glass electrodes were firstly calibrated and then immersed in a pH 7.0 buffer solution. The buffer solution was then slowly titrated with either NaOH or HCl. At each titration step, the pH readings from the glass and antimony electrodes were recorded.

The effect of prolonged exposure of the electrode tip to desiccation and oxygen were also tested and reported elsewhere .

2.4

Study participants

A pilot study was used to estimate the required sample size. We aimed to detect a pH difference ⿥0.5 between awake and asleep readings using a repeated measurements study design. Setting both α-error and β-error (95% power) to 0.05 (one-tailed test), we estimated that eleven participants were needed.

Participants (N = 11; mean age = 31.1 ± 6.9 years) were recruited among University of Otago staff and students. The following exclusion criteria were applied: smoking, gastro-oesophageal reflux disease, tooth wear, active caries, alcoholism, sleep disordered breathing, eating disorders, and intake of medication at enrolment. The study protocol was approved by the local Ethics Committee (H13/014) and a written informed consent was collected from all participants.

2.5

Oral appliance

The wireless device was embedded in a vacuum-formed oral appliance within two layers of hard-elastic polyethylene terephthalate glycol (PET-G; Duran ^® 0.5 ÿ 125 mm, Scheu Dental GmbH, Iserlohn, Germany). The device was secured to the dental cast using soft silicone (Sil-Kitt Clear, Scheu-Dental GmbH, Iserlohn, Germany). The pH probes were positioned close to the palatal surface of the upper central incisors in eight participants and more distally in three participants. These sites were chosen because they are most frequently affected by erosive tooth wear . The two PET-G foils were sealed using two sealants (Duralay, Reliance Dental, IL, USA; and 215-CTH-UR-SR, Dymax, Torrington, Connecticut, USA). The oral appliance with the embedded PCBs was then smoothed to optimise fitting and improve comfort ( Fig. 1 b).

2.6

Procedure

The experiment consisted of a clinical and an experimental session separated by at least one week. During the clinical session, the subjects were informed about the procedures and clinically evaluated to assess their eligibility for inclusion in the study. Alginate dental impressions (Kromopan, Lascod, Florence, Italy) of the maxillary arch were taken and poured with stone (Vel-Mix Stone type IV, Kerr, USA).

Prior to commencement of the 24-h study, the wireless units were embedded in the oral appliance and then calibrated for pH and temperature measurements using the custom-made software application. The temperature measurements were calibrated by immersing the appliance firstly into cold water and then warm tap water. Then the pH measurements were calibrated using a pH 7.0 (±0.02) and then a pH 4.01 (±0.02) buffer solution (Restech, San Diego, California, USA).

Once the device was calibrated, the participants were required to perform two standardised tasks that included: 1) three swallows of 10 ml of still water (NZ Natural Spring, Frucor, Kaiapoi, New Zealand; pH 7.2), one swallow every 1 min; and 2) three swallows of 10 ml of orange juice (McCoy, Frucor; pH 4.4), one swallow every 5 min. Both beverages were at room temperature (21 °C).

After completion of the standardised tasks, participants were free to continue with their daily activities and were asked to wear the intra-oral appliance for a period of 24 h. They were also given instructions on how to use the smartphone software. The participants were requested to keep the smartphone within approximately 2 m of the wireless device at all times to ensure a stable connection. The smartphone vibrated in the event of signal loss thus alerting the participant to re-establish connection.

Beverage intake and the main activities performed were recorded via smartphone software as well as in a logbook. The participants entered the time when the appliance was removed and replaced back into the mouth, as well as the sleep time, which was defined as the time the bedroom light was switched off until the participants first opened their eyes in the morning. The software also allowed participants to record the start and stop time of other casual activities, such as drinking, showering or exercise. When the ⿿activity stop⿿ button was pressed, participants were prompted to enter the type of activity that had been done.

Participants were requested to wear the intra-oral appliance at all times except during chewing and tooth-brushing. When not worn, the appliance was stored in a plastic container and kept wet using gauze moistened in distilled water.

2.7

Data analysis

The wireless appliance transmitted (0.5 Hz) the following information to the smart phone: unit ID, a data stamp, raw pH, temperature, and remaining battery voltage. Signals were further processed on-phone by adding a time stamp, the calibrated pH and temperature signals, and four activity markers (sleep start/stop, device in/out, drinking, other activity), which were stored as binary data. Data collected were stored on phone as comma separated values (CSV) files for subsequent off-line analyses. These analyses included a data quality check with removal of pH values outside the optimal range of the antimony electrode, as determined from laboratory experiments (Appendix A). The activity markers were used to cut the signal portions where the intra-oral appliance was removed and to identify tasks, such as drinking, sleeping or other activities.

The mean individual intra-oral pH and temperature while awake and asleep were calculated by averaging the corresponding signals delimited by the sleep markers. The standardised swallowing tasks were assessed by calculating the minimum intra-oral pH value and the recovery time. This was defined as the time needed for the intra-oral pH to return to its baseline value after a swallow of a drink.

The data collected were analysed using conventional descriptive statistics, linear regression, and a linear mixed-effects model. The response variables of the mixed model analysis were ⿿pH⿿ and ⿿temperature⿿, the variables ⿿time⿿ (either asleep or awake) and ⿿participant⿿ was entered as fixed and random factor, respectively. All analyses were performed using SPSS (20.0, IBM, Chicago, Illinois, USA). Statistical significance was accepted at P < 0.05.

2.1

Development of the wireless device

The wireless device ( Fig. 1 a) included a power supply printed circuit board (PCB; L ÿ W ÿ H: 14.0 ÿ 10.0 ÿ 0.8 mm) and a main PCB (L ÿ W ÿ H: 16.0 ÿ 10.5 ÿ 0.8 mm; Kamahi Electronics, Dunedin, New Zealand). The power supply PCB hosted a lithium magnesium di-oxide battery (CR1025, Renata, Switzerland), which provided sufficient power to collect data for >2 weeks. The main PCB included: an amplifier (Zerø-Crossover Rail-to-rail I/O operational amplifier, Texas Instruments, Dallas, Texas, USA); a microcontroller (PIC16FLF1825, Microchip Technology Incorporation, USA); a linear active thermistor (MCP9700AT, Microchip Technology Incorporation, Minnesota, USA); and an ANT ⁺ ultra-low power single chip (NRF24AP2, Dynastream Innovation, Trondheim, Norway). The pH and temperature measurements were transmitted to an ANT ⁺ -supported smartphone (Xperia M2, Sony, Tokyo, Japan) once every two seconds (0.5 Hz) using the Industrial, Scientific and Medical band (2.4 GHz). During each transmission, the radiofrequency transmitter only operated for 0.2 ms and otherwise remained off. This device fully complies with the New Zealand Standard for radiofrequency field exposure NZS 2772.1-1999. A small (ÿ = 2.4 mm) pH antimony electrode (Primus, Restech, San Diego, California, USA) was connected to the main PCB. The antimony electrode detects pH in aerosolised droplets without requiring full immersion or contact with fluid for electrical continuity .

Example of a fully assembled wireless device. a) The tip of antimony electrode (see arrow) is attached to the main printed circuit board (left hand side). b) wireless unit embedded in a vacuum-formed splint, with the antimony electrode tip (see arrow) positioned close to the palatal surface of the upper central incisors.

2.2

Software application

An Android software application was developed for the calibration, monitoring and recording of pH and temperature by the smart phone. The application was designed to be user-friendly, showing real-time dynamic charts of pH and temperature values (Appendix B). The graphing library ⿿achartengine⿿ ( www.achartengine.org ) was used to create the graphs. On-phone calibration was based on the standard two-point temperature and pH calibration process. The application saved individual log files for each recording session, which included basic demographic data.

2.3

Device testing and validation

In vitro experiments were conducted to test the accuracy and precision of the device. These experiments were conducted with the wireless unit not incorporated in an oral appliance. The accuracy of the thermistor was tested against a laboratory thermometer (Brannan thermometers, Cleator Moor, Cumbria, England), while heating the wireless unit with a laboratory incubator (Laboratory equipment Ptw, Marrickville, New South Wales, Australia).

The effect of temperature on the antimony pH electrode was tested using pH 7.4 phosphate buffered saline solution (Sigma-Aldrich ^® , St. Louis, Missouri, USA), in water baths set at 25, 35, or 45 ° C. The reading stability was tested by continuously measuring pH with the antimony electrode at a constant temperature (23.5 ° C) and pH (7.0) for 24 h.

The accuracy of the antimony electrode was tested against a standard glass pH electrode (PL-700 PVS, GOnDO Electronic, Taipei, Taiwan). The antimony and glass electrodes were firstly calibrated and then immersed in a pH 7.0 buffer solution. The buffer solution was then slowly titrated with either NaOH or HCl. At each titration step, the pH readings from the glass and antimony electrodes were recorded.

The effect of prolonged exposure of the electrode tip to desiccation and oxygen were also tested and reported elsewhere .

2.4

Study participants

A pilot study was used to estimate the required sample size. We aimed to detect a pH difference ⿥0.5 between awake and asleep readings using a repeated measurements study design. Setting both α-error and β-error (95% power) to 0.05 (one-tailed test), we estimated that eleven participants were needed.

Participants (N = 11; mean age = 31.1 ± 6.9 years) were recruited among University of Otago staff and students. The following exclusion criteria were applied: smoking, gastro-oesophageal reflux disease, tooth wear, active caries, alcoholism, sleep disordered breathing, eating disorders, and intake of medication at enrolment. The study protocol was approved by the local Ethics Committee (H13/014) and a written informed consent was collected from all participants.

2.5

Oral appliance

The wireless device was embedded in a vacuum-formed oral appliance within two layers of hard-elastic polyethylene terephthalate glycol (PET-G; Duran ^® 0.5 ÿ 125 mm, Scheu Dental GmbH, Iserlohn, Germany). The device was secured to the dental cast using soft silicone (Sil-Kitt Clear, Scheu-Dental GmbH, Iserlohn, Germany). The pH probes were positioned close to the palatal surface of the upper central incisors in eight participants and more distally in three participants. These sites were chosen because they are most frequently affected by erosive tooth wear . The two PET-G foils were sealed using two sealants (Duralay, Reliance Dental, IL, USA; and 215-CTH-UR-SR, Dymax, Torrington, Connecticut, USA). The oral appliance with the embedded PCBs was then smoothed to optimise fitting and improve comfort ( Fig. 1 b).

2.6

Procedure

The experiment consisted of a clinical and an experimental session separated by at least one week. During the clinical session, the subjects were informed about the procedures and clinically evaluated to assess their eligibility for inclusion in the study. Alginate dental impressions (Kromopan, Lascod, Florence, Italy) of the maxillary arch were taken and poured with stone (Vel-Mix Stone type IV, Kerr, USA).

Prior to commencement of the 24-h study, the wireless units were embedded in the oral appliance and then calibrated for pH and temperature measurements using the custom-made software application. The temperature measurements were calibrated by immersing the appliance firstly into cold water and then warm tap water. Then the pH measurements were calibrated using a pH 7.0 (±0.02) and then a pH 4.01 (±0.02) buffer solution (Restech, San Diego, California, USA).

Once the device was calibrated, the participants were required to perform two standardised tasks that included: 1) three swallows of 10 ml of still water (NZ Natural Spring, Frucor, Kaiapoi, New Zealand; pH 7.2), one swallow every 1 min; and 2) three swallows of 10 ml of orange juice (McCoy, Frucor; pH 4.4), one swallow every 5 min. Both beverages were at room temperature (21 °C).

After completion of the standardised tasks, participants were free to continue with their daily activities and were asked to wear the intra-oral appliance for a period of 24 h. They were also given instructions on how to use the smartphone software. The participants were requested to keep the smartphone within approximately 2 m of the wireless device at all times to ensure a stable connection. The smartphone vibrated in the event of signal loss thus alerting the participant to re-establish connection.

Beverage intake and the main activities performed were recorded via smartphone software as well as in a logbook. The participants entered the time when the appliance was removed and replaced back into the mouth, as well as the sleep time, which was defined as the time the bedroom light was switched off until the participants first opened their eyes in the morning. The software also allowed participants to record the start and stop time of other casual activities, such as drinking, showering or exercise. When the ⿿activity stop⿿ button was pressed, participants were prompted to enter the type of activity that had been done.

Participants were requested to wear the intra-oral appliance at all times except during chewing and tooth-brushing. When not worn, the appliance was stored in a plastic container and kept wet using gauze moistened in distilled water.

2.7

Data analysis

The wireless appliance transmitted (0.5 Hz) the following information to the smart phone: unit ID, a data stamp, raw pH, temperature, and remaining battery voltage. Signals were further processed on-phone by adding a time stamp, the calibrated pH and temperature signals, and four activity markers (sleep start/stop, device in/out, drinking, other activity), which were stored as binary data. Data collected were stored on phone as comma separated values (CSV) files for subsequent off-line analyses. These analyses included a data quality check with removal of pH values outside the optimal range of the antimony electrode, as determined from laboratory experiments (Appendix A). The activity markers were used to cut the signal portions where the intra-oral appliance was removed and to identify tasks, such as drinking, sleeping or other activities.

The mean individual intra-oral pH and temperature while awake and asleep were calculated by averaging the corresponding signals delimited by the sleep markers. The standardised swallowing tasks were assessed by calculating the minimum intra-oral pH value and the recovery time. This was defined as the time needed for the intra-oral pH to return to its baseline value after a swallow of a drink.

The data collected were analysed using conventional descriptive statistics, linear regression, and a linear mixed-effects model. The response variables of the mixed model analysis were ⿿pH⿿ and ⿿temperature⿿, the variables ⿿time⿿ (either asleep or awake) and ⿿participant⿿ was entered as fixed and random factor, respectively. All analyses were performed using SPSS (20.0, IBM, Chicago, Illinois, USA). Statistical significance was accepted at P < 0.05.