Abstract
Purpose
Jaw-stretching devices, including the Amplification, Resistance, and Kinetics of the Jaw (ARK-JSD), are an effective option for treating trismus after head and neck cancer (HNC) treatment. The force, however, that is applied to the patient’s jaw is unknown.
Methods
Ten ARK-JSD devices were constructed for each of the levels of resistance (total of 30 samples). Each sample was tested using a Universal Testing Machine (UTM).
Results
The easy, medium, and hard ARK-JSD had a mean maximum force of 12.3, 21.0, and 32.7 Newtons (N) at a mean interincisal distance (IID) of 8.0 mm, 13.0 mm, and 16.0 mm, respectively. The force varied by 6.9 N for the easy and 24.1 N for the hard ARK-JSD. Fatigue analysis demonstrated up to 5.5 N loss of force over 10 weeks.
Conclusion
The ARK-JSD is a low-cost trismus device that can force between 12.3 and 32.7 N. The variation in resistance may impact efficacy. Understanding this variation will assist clinicians and patients using the ARK-JSD for trismus therapy.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Trismus (restricted mouth opening) is a common problem after head and neck cancer treatment, particularly when multimodality therapy (surgery and/or chemoradiotherapy) is required for advanced cancers [1]. Trismus impairs access to the mouth for self-administered oral hygiene and professional dental care, which accelerates dental caries and loss of dentition [2]. It also can make eating in public more challenging, placing cancer patients with xerostomia and dysphagia at risk of malnutrition [3]. Together, these side effects lead to anxiety, impaired socialisation and even financial hardship through loss of employment [4,5,6,7]. Whilst there is evidence showing that jaw-stretching devices are effective in the treatment of trismus, commercial devices are often under-utilised because of their high cost [8]. The efficacy and safety of such devices may also be compromised because the force applied to the jaw is unknown and unregulated. This means that the patient determines what force is appropriate, and whilst therapy is often supervised by trained professionals, there is no way to know whether the force applied is sufficient to improve mouth opening or excessive in patients with compromised dentition or bone integrity.
Amplification, Resistance, and Kinetics of the Jaw (ARK-J) is a trismus training course which trains clinicians in trismus assessment and therapy. It also teaches clinicians how to make the homemade ARK-J Stretching Device (ARK-JSD) as a replacement for the common practice of using stacked tongue depressors for trismus therapy. The ARK-JSD’s key features are low cost, portability, and three levels of resistance (easy/medium/hard). These features allow patients who are unable to afford commercial devices to access a trismus therapy device which can both passively and actively exercise the jaw. The three different ARK-JSD construction options allow patients to progress by increasing the mechanical load to meet their rehabilitation goals. Whilst the ARK-J programme adheres to the exercise physiology principle of load progression [9], the specific load for each level of resistance has not been published. Furthermore, as the ARK-JSD is constructed by the clinician, it is unknown whether there is substantial variation in the force generated between each individual device for a given level of resistance and whether this force changes with time or use. This study aimed to define the mean load and sample variation of individually constructed ARK-JSDs at each level of resistance.
Materials and methods
Ethical approval was not required for this non-biological in vitro study.
Device assembly
The first author (EC) followed instructions provided by the ARK-J construction guide to make ten ARK-JSD for each level of resistance (easy/medium/hard), giving a total of 30 samples (Fig. 1). A description of the ARK-JSD is available on https://www.youtube.com/watch?v=9NWFCxbJ96Y; however, the construction guide is only available to clinicians who have undertaken the ARK-J course. The device is inserted between the teeth and dentition by narrowing the outer wings; once the device is resting on the dentition or gingiva, the narrowed wings can be released deploying force downwards upon the mandible. Higher resistances are achieved by more tongue depressors added to the design. IID usually refers to the measure between the top and bottom incisors and is measured in millimetres. For the purposes of this study, this number was calculated by measuring from the upper surface of the top tongue depressor to the lower surface of the bottom tongue depressor. Adding resistance increases the IID required to fit the ARK-JSD in the mouth. The ARK-JSD is made to carry out passive (stretch open) and active (bite down) exercises which involve the user to move between minimal IID (mouth biting down and closing the device) to maximal IID (stretching open the device).
Force and interincisal distance (IID) assessment
Assessors (KC and AL) were blinded, and force-displacement curves were generated for each of the 30 samples in random order using a TMA-10W Universal Testing Machine (UTM) (Test Machine Australia, Melbourne, Australia) as shown in Fig. 2. A testing jig was designed to prevent the device from slipping whilst under load, and the force was measured corresponding to the interincisal distance (IID) in dentate patients. The jig was 3D printed using a Form3 Stereolithography (SLA) printer and Durable Resin v1 (Formlabs, Somerville, MA, USA), as well as a Raise Pro 2 Fuse Deposition Modelling (FDM) printer and polylactic acid (PLA) filament (Raise3D Technologies, Inc., Irvine, CA 92618, USA). Two frame-holding components were fitted onto the ARK-JSD and connected to two ball joints. The lower ball joint was fitted into a 3D-printed base disc that was fixed to the TMA-10W UTM stationary bottom plate. The compression upper plate, which was coupled to a load cell and movable cross head, was inserted into the upper ball joint’s socket. When the ARK-JSD is loaded, the contacts between the ball joints and the holding components are aligned and remain straight.
Cyclic fatigue testing
Cyclic testing was performed to assess fatigue over 1750 cycles, replicating a typical exercise regime for trismus therapy of 25 repetitions per day for 30 s, 7 days per week, for 10 weeks, oscillating between minimum and maximum IID; these values represent the full range of each device. Cyclic fatigue testing was performed using the same jig and the UTM setup for three ARK-JSDs (one from each level of resistance).
Statistical analysis
Statistical analysis was carried out with system software R i386 3.2.2 (The R Foundation for Statistical Computing). Clinically meaningful variation in force was defined as > 5 N, taken as ± 2.5 N from the mean force generated for each ARK-JSD level of resistance. This value was selected based on the experience of the authors using a purpose-built trismus device (Restorabite™) which does have known regulated and incremental force values, where a difference in force of 5 N could consistently be detected by patients. The linearity of force IID curves was assessed using Pearson’s correlation coefficient (ρ). High linearity was defined as ρ > 0.7, moderate linearity was defined as ρ between 0.50 and 0.7, and poor linearity if ρ < 0.5 [10]. Force comparisons were standardised according to the minimum and maximal IIDs.
Results
IID
The minimum IID for the easy, medium, and hard devices was 8 mm, 13 mm, and 16 mm, respectively. These differences result from the height of the tongue depressors stacked together in the upper and lower part of the frame. The mean maximum IID for the easy, medium, and hard levels of resistance was 46.3 mm (range 43.9–49.7), 47.8 mm (range 42.3–52.3), and 50.1 mm (45.2–53.1) (Fig. 3).
Force (Table 1)
The maximum force generated by the easy ARK-JSD (12.3 ± 2.16 N) was significantly different to the medium ARK-JSD (21.0 ± 5.14 N, p = 0.0003), which was significantly different to the mean maximum force generated by the hard ARK-JSD (32.7 ± 6.93 N, p = 0.0005). The maximum force generated by the easy, medium, and hard ARK-JSDs varied by 6.9 N (9.3–16.1 N), 17.6 N (15.4–32.9 N), and 24.1 N (24.7–48.8 N), respectively. When compared to the mean force generated for each level of resistance, this represented a clinically meaningful difference in force (5 N) in 30% of samples of easy, 40% of medium, and 70% of hard ARK-JSDs. The force–displacement curves (Fig. 4) showed poor linearity for the easy ARK-JSD (ρ = 49.4 ± 1.8) and moderate linearity for both the medium (ρ = 54.2 ± 1.5) and hard ARK-JSDs (ρ = 58.6 ± 2.4). They also depict the relationship between IID and force, where in each ARK-JSD, as the IID increased, the force decreased.
Cyclic fatigue testing
The easy, medium, and hard ARK-JSD experienced a loss in force of 0.4 N (16.1–15.7 N), 3.4 N (25.2–21.8 N), and 5.5 N (48.8–43.3 N), respectively, over accelerated 10 weeks of cyclic testing (1750 cycles of 30 s). The loss of force arose from three factors shown in Fig. 5: (a) changes in maximal IID, (b) misalignment of the outer frame, and (c) loosening of the tape.
Discussion
This study is the first to describe the objective resistance provided by the ARK-JSD, supporting its use as a low-cost alternative to commercial trismus devices and an evidence-based alternative to stacked tongue depressors. The forces generated by the ARK-JSD all fall below the reported fracture threshold load for a healthy mandible (431–725 N) [11] and below normal bite forces tolerated by healthy dentition (83.9–1642.8 N) [12]. The amount of force exerted was much higher when the ARK-JSD was in the closed position, where the IID was low, and got lower as the IID increased. The force applied by stacked tongue depressors and ARK-JSD is concentrated over a smaller area than TheraBite®; however, the capacity to manipulate the position within the mouth is a distinct advantage of both of these rehabilitation options. Whilst the ARK-JSD is safe to use in a healthy population, the mandibular fracture and dental damage threshold for those recovering from head and neck cancer treatment are unknown and may be considerably lower. We have found that there are several key device reliability factors for clinicians to be aware of. The first is that there is clinically meaningful variation in the maximal force provided for each level of resistance. This may impact the amount of stretch that a patient is able to achieve and impair rehabilitation when swapping between devices, either due to device failure or when progressing between different levels of resistance. The second is the loss of force over time, with the hard ARK-JSD losing over 5.5 N. This is important given that stretching and strengthening generally require force to increase over time for clinical gains.
The ARK-JSD is an affordable trismus device that offers passive and active stretching exercises at three different levels of resistance. It was created to address some of the major barriers to accessing commercial trismus devices such as cost. Whilst existing literature supports the use of commercial trismus devices (e.g. TheraBite®) for people recovering from head and neck cancer [8], access to best-practice care is not always affordable or available. The ARK-JSD design is similar to the Engstrom device. The Engstrom device has been evaluated in comparison to TheraBite® and found to improve mouth opening by a mean IID increase of 6.4 mm [13] and 6.2 mm [14] over a 10-week period. Whilst ARK-JSD has not been evaluated in a prospective trial, the added benefit of three resistance levels that allows for the progression of exercise difficulty is promising. Its low cost and ease of construction using readily available materials make it accessible to patients regardless of socio-economic status, a critical factor lacking in most commercially available trismus devices.
Safety is a primary concern for medical devices, and there is a paucity of data regarding the force that jaw-stretching devices are capable of exerting. This is particularly important in devices, such as the ARK-JSD that rely on a resistance mechanism that is not controlled by the user. Hence, it is the responsibility of the prescribing clinician to understand the maximal force that the device can potentially deliver. Variables such as treatment modalities, age, smoking status, medications, and bone density will lower the dental or jaw fracture threshold, and, in most cases, the ‘safe’ force that can be applied to a jaw following head and neck cancer is unknown [15]. There are currently no simple methods to determine the safe force threshold based on individual patient factors. Instead, trismus therapy replicates guidelines from static stretching literature where the patient stops the intensification of stretches when (or ideally prior to) experiencing pain. In patients recovering from head and neck cancer treatment where sensation is often compromised, the pain signal for force overload may be impaired or absent thus increasing the risk of fracture. Whilst finite element modelling (FEM) based on individual computerized tomography (CT) data could be used to quantify fracture thresholds, this technology is not clinically available, validated, nor practicable.
The ARK-JSD is not designed to, nor would it be expected to meet the durability of commercially made devices. However, whilst the construction protocol was followed for assembling each ARK-JSD unit, there was substantial variation in the maximal force for each resistance level. The greatest variation was observed in the hard ARK-JSD (24.7–48.8 N) which overlapped with the medium frame. Construction variables include how tight a clinician wraps the tape around the device, the presence of any splintering of the tongue depressors in the process of construction, and the position of the wedge within the outer frame (Fig. 5). This variation may affect the ability of patients with trismus to continue to improve their IID over time and should be factored into any rehabilitation plan or if this device was subject to a clinical trial. Despite the variation, there were statistically significant and clinically meaningful differences in the resistance provided by the easy, medium, and hard ARK-JSDs, with sufficient within-level consistency to be effective in most clinical scenarios (Table 1).
Limitations
There were several limitations inherent in this study including potential inconsistencies in device assembly and limited sample size, and that cyclic testing was not performed on all devices. Furthermore, there is no data regarding what constitutes a clinically meaningful difference in force for trismus therapy. The authors selected 5 N based on their clinical experience; however, this value requires validation. Determining the minimum amount of force change that is discernible in trismus and healthy populations would serve to improve the validity of these findings.
Conclusion
This is the first study to the author’s knowledge that comprehensively evaluates the force applied to the jaw from a mechanically loaded device. The findings have implications for both treatment efficacy and safety. The ARK-JSD is a novel, low-cost device which features three differing levels of resistance averaging 12.3 N, 21.0 N, and 32.72 N, respectively. Within each level, there is a substantial force variation, and cyclic fatigue testing demonstrates a reduction of up to 5.5 N over 10 weeks. Clinicians should be aware of not only its limitations but also the opportunities offered by this device.
Data availability
The datasets generated and/or analysed during the current study are available from the corresponding author on reasonable request.
References
Johnson J, van As-Brooks CJ, Fagerberg-Mohlin B, Finizia C (2010) Trismus in head and neck cancer patients in Sweden: incidence and risk factors. Med Sci Monit 16(6):CR278-82
Benjamin RM (2010) Oral health: the silent epidemic. Public Health Rep 125(2):158–159
Lee R, Slevin N, Musgrove B, Swindell R, Molassiotis A (2012) Prediction of post-treatment trismus in head and neck cancer patients. Br J Oral Maxillofac Surg 50(4):328–332
Astradsson T, Laurell G, Ahlberg A, Nikolaidis P, Johansson H, Ehrsson YT (2018) Trismus in patients with head and neck cancer and 5-year overall survival. Acta Otolaryngol 138(12):1123–1127
Dhanrajani PJ, Jonaidel O (2002) Trismus: aetiology, differential diagnosis and treatment. Dent Updat 29(88–92):94
Chee S, Byrnes YM, Chorath KT, Rajasekaran K, Deng J (2021) Interventions for trismus in head and neck cancer patients: a systematic review of randomized controlled trials. Integr Cancer Ther 20:15347354211006474
Vissink A, Jansma J, Spijkervet FK, Burlage FR, Coppes RP (2003) Oral sequelae of head and neck radiotherapy. Crit Rev Oral Biol Med 14(3):199–212
Charters E, Dunn M, Cheng K, Aung V, Mukherjee P, Froggatt C, Dusseldorp J, Clark J (2022) Trismus therapy devices: a systematic review. Oral Oncol 126:105728
La Scala Teixeira CV, Evangelista AL, Pereira PEA, Da Silva-Grigoletto ME, Bocalini DS, Behm DG (2019) Complexity: a novel load progression strategy in strength training. Front Physiol 10:839
Cohen J (1988) Statistical power analysis for the behavioural sciences, 2nd edn. Lawrence Erlbaum Associates, New Jersey, NY
Rowe NL (1994) Aetiology of injury Chap. 2. In: Rowe NL, William JLI (eds) Maxillofacial injuries, vol 1, 2nd edn. Churchill Living Stone. New York, pp 39–50
van Vuuren L, Broadbent JM, Duncan WJ, Waddell JN (2019) Maximum voluntary bite force, occlusal contact points and associated stresses on posterior teeth. J R Soc N Z 50(1):132–143
Pauli N, Fagerberg-Mohlin B, Andréll P, Finizia C (2014) Exercise intervention for the treatment of trismus in head and neck cancer. Acta Oncol 53(4):502–509
Karlsson O, Karlsson T, Pauli N, Andréll P, Finizia C (2021) Jaw exercise therapy for the treatment of trismus in head and neck cancer: a prospective three-year follow-up study. Support Care Cancer 29:3793–3800
Kubota H, Miyawaki D, Mukumoto N, Ishihara T, Matsumura M, Hasegawa T, Akashi M, Kiyota N, Shinomiya H, Teshima M, Nibu KI, Sasaki R (2021) Risk factors for osteoradionecrosis of the jaw in patients with head and neck squamous cell carcinoma. Radiat Oncol 16(1):1
Acknowledgements
We would like to thank the Lang Walker Family Foundation, the Sydney Local Health District, and the Cancer Institute of New South Wales (CINSW 2020/TPG2081) for supporting equipment, salary, and materials for this paper.
Funding
Open Access funding enabled and organized by CAUL and its Member Institutions. We would like to thank the Lang Walker Family Foundation, the Sydney Local Health District, and the Cancer Institute of New South Wales (CINSW 2020/TPG2081) for supporting equipment, salary, and materials for this paper.
Author information
Authors and Affiliations
Contributions
Author 1 (co-first author) contributed to the conception, design, and interpretation; drafted, and critically revised the manuscript. Author 2 (co-first author) contributed to the conception, design, data acquisition, and interpretation and critically revised the manuscript. Author 3 contributed to the conception and design and critically revised the manuscript. Author 4 contributed to data acquisition and interpretation and critically revised the manuscript. Author 5 contributed to data acquisition and interpretation and critically revised the manuscript. Author 6 contributed to data acquisition and interpretation and critically revised the manuscript. Author 7 contributed to the conception, design, and interpretation and critically revised the manuscript. All authors gave their final approval and agree to be accountable for all aspects of the work.
Corresponding author
Ethics declarations
Ethics approval and consent to participate
Ethical approval was not required for this non-biological in vitro study.
Consent for publication
All authors gave their final approval and agree to be accountable for all aspects of the work.
Competing interests
The authors declare no competing interests.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Emma Charters and Kai Cheng are co-first authors.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Charters, E., Cheng, K., Dunn, M. et al. Amplification, Resistance, and Kinetics of the Jaw Stretching Device (ARK-JSD): analysis of the force variation and implications for trismus therapy. Oral Maxillofac Surg 28, 877–883 (2024). https://doi.org/10.1007/s10006-024-01218-1
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10006-024-01218-1