Orofacial pain (OFP) is a term used to describe pain affecting the face and/or the oral structures.1 The prevalence of OFP in the general population is up to 15% with a high prevalence rate among young and middle-aged women.2 Chronic OFP conditions can be difficult to diagnose due to the varied signs and symptoms, the complex anatomy of the region and lack of objective testing in most cases.3 OFP conditions can be categorized into myofascial, commonly known as temporomandibular disorders (TMDs) and neuropathies, which include persistent idiopathic facial pain (PIFP), persistent idiopathic dentoalveolar pain (PIDP), idiopathic burning mouth syndrome (BMS) and trigeminal neuralgia (TN) etc.4 As the underlying etiology and pathogenesis of these conditions are mostly unknown, treatment is nonspecific and comprises management of the symptoms, rather than addressing the underlying disease process. Hence, improvement is not assured, and most cases will need lifetime pain management.5 The financial burden of facial pain is approximately 2032 USD in 2017 per person per 6-month period.6 Furthermore, patients with chronic OFP can have difficulty maintaining nutrition and social interactions. As such, OFP conditions have a huge emotional and financial impact on society and the individuals involved.
Small fiber neuropathy (SFN) is a disorder of thinly myelinated A-delta and non-myelinated C- fibers.7 The clinical presentation is heterogenous and characterized by clinical signs of neuropathy with either a positive skin biopsy or positive autonomic function testing or both.8,9 Nonspecific symptoms such as fatigue, cramps, and deep aching pain can also occur due to involvement of polymodal muscle afferents.10 The diagnosis of SFN is based on typical complaints, combined with abnormal intraepidermal nerve fiber density in skin biopsy and/or abnormal temperature threshold testing levels, without signs of large nerve fiber involvement.11 SFN can be length-dependent involving a typical sock and glove pattern, non-length dependent where different parts of the body can be involved in a patchy pattern or focal involving a circumscribed area only. Focal and non-length dependent (NLD) SFNs have been shown to involve the orofacial region.12,13 For instance, reduced small fiber nerve density is an underlying cause in idiopathic burning mouth syndrome.12,14,15 Also, association has been shown between SFN and several chronic pain conditions, such as fibromyalgia, chronic regional pain syndromes, and unexplained widespread chronic pain conditions.16,17 Therefore, it is possible that certain patients presenting with chronic OFP conditions can also have an underlying SFN.
Our study aims to assess the prevalence of OFP in a large cohort of patients with sensory and autonomic neuropathies and assess the correlation between OFP and results of skin biopsy testing, autonomic dysfunction, primary headaches, chronic nociceptive and neuropathic pain, psychological conditions, and individual patient factors, such as BMI and mean age.
Materials and MethodsEthics StatementThe study was performed following the standards of the Declaration of Helsinki. The study was approved by the Ethics Committee of Massachusetts General Hospital, Boston, Massachusetts (Protocol No. 2019P003169). A waiver of patient consent/authorization was approved by the Ethics Committee for this retrospective study. A waiver of consent/authorization was granted by IRB because of the difficulty in locating individuals who may have moved, the number of subjects and cost and use of limited research resources of locating individuals and sending letters and consent forms and the impact on the scientific validity of the study if only data of individuals from whom we were able to obtain informed consent was used.
The following tasks were undertaken to prevent the rights and welfare of the subjects to be adversely affected by the waiver of consent / authorization:
(1) identifiable data was stored securely with access limited to study staff.
(2) information resulting from this study would not have any important health/medical implications for subjects.
Study Design and Patient PopulationThis is a retrospective chart review of patients from the SFN registry, which is maintained by the Department of Neurology at Massachusetts General Hospital (MGH), Boston, USA. The registry is comprised of patients who have undergone diagnostic skin biopsy for SFN at MGH. The patients who are suspected of having small fiber neuropathy undergo work-ups with skin biopsy, electromyogram, and/or autonomic function tests and are included in this registry. The methodology of these methods is described by Zirpoli et al.18
All patients in this Registry from 2018–2020 present were included. The charts of these patients were retrospectively reviewed for the presence of OFP. The OFP data was evaluated by an OFP specialist (SH). OFP symptoms were divided into two categories: 1. Myofascial facial pain, which includes masticatory myalgias and/or arthralgias of the temporomandibular joint (TMJ)- collectively known as Temporomandibular Joint Disorders (TMDs), 2. Orofacial dysesthesia, which includes neuropathic pain or paresthesia or hypersensitivity in the mouth and/or face.4
Other data such as patient demographics-the age at biopsy, gender, patient characteristics- body mass index (BMI), history of chronic pain (neuropathic or nociceptive) in other parts of the body, history of migraines and other headaches, history of psychological conditions, such as anxiety, depression, obsessive compulsive disorder, bipolar disorder etc. were collected. Data on skin biopsy and presence of autonomic symptoms was collected and analyzed as well.
SFN data including skin biopsy and autonomic function testing were collected and analyzed.
Inclusion CriteriaPatients of all gender and ages who have undergone diagnostic skin biopsy for SFN at MGH.
Exclusion CriteriaOFP, where the underlying cause of pain was a known pathology, was not considered as OFP condition for this study.
Primary OutcomePrevalence of OFP in patients with chronic sensory and autonomic neuropathies.
Secondary OutcomeCorrelation between OFP and results of skin biopsy, presence of autonomic dysfunction, headaches, chronic nociceptive and neuropathic pain conditions, psychological conditions, age, and BMI.
Statistical AnalysisData from the SFN registry and electronic patient records were recorded and de-identified. The results of skin biopsy, presence of autonomic dysfunction, chronic peripheral and other systemic neuropathic and nociceptive symptoms, migraines and other primary headaches, and psychological conditions were analyzed for their statistical correlation with OFP symptoms. Mean, range, frequencies were used for calculating descriptive variables. Statistical comparison was performed using Student’s t-test for continuous variables and chi-squared test for categorical variables. Statistical significance was set at p value<0.05.
ResultsCharts of 450 patients who had undergone diagnostic skin biopsy to establish SFN diagnosis were reviewed. A breakdown of the patient demographics with respect to TMDs and orofacial dysesthesia is shown in Table 1. Tables 2–4 show the differences between patients with OFP and without OFP, with TMDs and without TMD and with and without orofacial dysesthesia, respectively.
Table 1 Prevalence of Orofacial Pain in Patients Who Underwent Skin Biopsy at MGH (Total Patients n=450)
Table 2 Comparison of Patients with OFP Vs No OFP Symptoms
Table 3 Comparison of Patients with Myofascial Symptoms/TMDs Vs No Myofascial TMD Symptoms
Table 4 Comparison of Patients with Orofacial Dysesthesia Vs No Orofacial Dysesthesia Symptoms
The mean age (range, SD) of the cohort was 46.77 (18–81, 14.89) years and female: male ratio of the cohort was 2.4:1. 61.33% (n=276) of these patients had peripheral neuropathies, 69.56% (n=313) had nociceptive pain symptoms in other regions of the body, 35.11% (n=158) had migraines and 47.56% (n= 214) had other primary headaches. 24% (n=108) of these patients also had psychological comorbidities to include but not limited to depression, anxiety, panic disorder, attention deficit disorder etc.
22.67% (n=102) patients with sensory and/or autonomic neuropathic symptoms had OFP symptoms– 39.2% (n=40/102) TMDS and 60.8% (n=62/102) orofacial dysesthesia. The mean (range) age at biopsy for all patients with OFP symptoms was 48.36 (20–81) years, female: male ratio 3.25:1, mean (range) BMI 26.28 (18.42–51.57).
There was no significant difference in mean age (p value 0.822) and no gender predilection (p value 0.129) was noted between patients with OFP when compared with the ones without OFP symptoms. Most patients (73.53%) with OFP symptoms were either overweight (BMI 25.0–29.9) or obese (BMI >30) and a significantly higher number of patients with OFP symptoms had a mean BMI >30 (p value 0.025). 51.96% (n=53) patients were overweight; 21.57% (n=22) were obese. Only 26.47% (n=27) were in the normal weight range or underweight (BMI <24.9).
Significant difference was noted in skin biopsy results between patients with and without OFP, with negative skin biopsy more prevalent in patients with OFP (p value=0.049). Dysautonomia symptoms were noted to be higher in patients with TMDs when compared to patients without TMDs (p value 0.030). Also, patients presenting with any type of OFP symptoms- TMDs and/or orofacial dysesthesia had significantly higher psychological comorbidities (p value 0.000). No significant correlation was noted between OFP and presence of other chronic pain conditions, such as, peripheral neuropathies (p value 0.739), nociceptive pain (p value 0.634), migraines (p value 0.323), and other primary headaches (p value 0.311).
When the patients with OFP symptoms were compared to the overall cohort, it was noted that autonomic symptoms were present in 50% (51/102) patients with OFP, which was comparable to the overall cohort 48.7% (219/450). Similarly, peripheral neuropathies were present in 62.7% (64/102) of OFP patients, which was comparable to the cohort 61.3% (276/450), migraines were present in 39.2% (40/102) of OFP patients as compared to 35.1% (158/450), other headaches in 52% (53/102) of OFP patients as compared to 47.5% (214/450) in overall cohort. Chronic nociceptive pain was present in 67.6% (69/102) patients with OFP, like the overall cohort where 69.6% (313/450) patients had chronic nociceptive pain conditions. Skin Biopsy results were positive in 15.7% (16/102) patients with OFP as compared to 22.9% (103/450) in the overall cohort.
DiscussionIn this study, we aimed to assess the prevalence of OFP in a large cohort of patients with sensory and/or autonomic neuropathies and found that more than 20% (n=102) of these patients had OFP. We speculate these numbers to be higher because this study has several limitations, which are mentioned below. Also, in this study, patients who had OFP symptoms presented with a high number of other chronic overlapping pain conditions, like migraines, which were present in 39.2% (n=40) patients, and other primary headaches and chronic nociceptive and neuropathic pain, in more than half the patients with OFP. This aligns with the concept of coexisting pain conditions, or chronic overlapping pain conditions (COPCs),19,20 a concept that has been recognized by the National Institutes of Health and the US Congress as a set of disorders that can occur simultaneously in patients and include, but should not be limited to, temporomandibular disorder (TMD), fibromyalgia (FM), irritable bowel syndrome (IBS), vulvodynia, chronic tension-type headache, migraine headaches to name a few. Collectively, these conditions are increasingly referred to.19,20 Most of these conditions are defined as idiopathic, ‘as not being able to be explained by injury or pathology in the tissues from which the pain originates’.21
The clinical presentation of SFN is heterogeneous, with no single clinical pattern fitting all presentations.7 SFN was thought to be rare, but an epidemiological study in the Netherlands reported an incidence of 12 cases per 100 000 inhabitants per year and a prevalence of 53 cases per 100,000.22 In the past few decades, an increasing number of studies widened the spectrum of diseases associated with small nerve fiber degeneration,23 such as fibromyalgia,24 chronic regional pain syndrome,25 painful erythromelalgia,26 burning mouth syndrome,12 etc.—conditions that are increasingly recognized to fall under COPC spectrum. A recent systematic review and meta-analysis showed fibromyalgia to be complicated by SFN in 49% of cases.24 Is it possible that the other conditions that overlap with fibromyalgia but are idiopathic, for example, TMDs and BMS, are also complicated by SFN?
Skin biopsy, which allows reliable quantification of intraepidermal nerve fiber density, has been a milestone for the diagnosis of SFN27 and is widely acknowledged as confirmatory diagnostic test with high diagnostic accuracy (sensitivity 94.35, specificity 91.9%)27 when combined with clinical symptoms. In this study, abnormal skin biopsy was noted in more than 1/5th of the total patients (22.9%, n=103) and in about 1/6th of the patients with OFP −15.7% (n=16) - signifying the presence of underlying SFN in this group of patients. SFN has been noted as an underlying cause in idiopathic BMS,12 where biopsy specimens were taken from the region of pain, that is, the tongue, to assess for the damage of peripheral nerve fibers. It is possible that a more localized biopsy specimen will be more specific and diagnostic when assessing SFN as the underlying cause of idiopathic OFP, especially when other peripheral symptoms are absent. Therefore, in our opinion, the statistical analysis showing a lower prevalence of OFP in abnormal skin biopsy patients is not meaningful. More biopsy techniques and local sites such as oral mucosa should be explored to assess for intraepidermal nerve fiber density in non-length dependent or focal SFN cases.
It is worth noting that half the patients in this study with OFP had dysautonomia, with significantly higher number of these patients being the ones with TMDs. It is possible that this could be due to a more centralized pain phenomenon in these patients rather than just a peripheral insult. In a study done by Durham et al, a high prevalence of painful temporomandibular joint disorders was noted in patients with autonomic dysfunction and Postural Orthostatic Hypotension.25,28 It is important to note that the correlation between OFP and autonomic dysfunction has not been studied widely. Very few studies exist that correlate facial pain with autonomic dysfunction. In another case-control study conducted by Leonard et al in patients with trigeminal neuralgia (TN), it was noted that patients with TN had autonomic nervous system dysfunction (tested with cardiac reactivity to cold pressor test) when compared to healthy controls.29 Systematic studies to further evaluate the existence of autonomic symptoms in patients with OFP are needed. Functional MRI studies can help us understand these central pain conditions.
OFP and TMDs have been associated with psychological comorbidities in many studies. In a large prospective case-control study, Orofacial Pain: Prospective Evaluation and Risk Assessment (OPPERA), psychological comorbidities were found to be causal determinants of TMD pain.30 Psychological comorbidities were noted to be significantly higher in patients with OFP symptoms in this cohort across all OFP diagnoses—TMD and/or orofacial dysesthesia.
Obesity and chronic pain have been associated, but the correlation is understudied and remains largely unknown.31 How obesity affects the trigeminal nociceptive system in humans, which is central to OFP conditions, remains unknown. Animal studies have shown that the trigeminal nociceptive processing, is abnormal in mice with obesity.32,33 Our study shows a significant correlation between chronic OFP and obesity. Considering a high burden of these conditions on both individuals and society, this correlation needs further investigations.
LimitationsThis is a retrospective study, and some data could not be interpreted. The cohort was not specifically focused on studying the OFP conditions. Therefore, there is a possibility that this study underestimates the prevalence of OFP in this cohort who underwent a work-up for SFN due to the following reasons—most SFN questionnaires, like the Small Fiber Neuropathy and Symptoms Inventory Questionnaire (SFN SIQ) that was used in this cohort, are designed to assess distal neuropathies and autonomic symptoms, hence patients do not tend to mention facial pain unless prompted or specifically questioned by their provider. The biopsy specimens were not taken from the region of orofacial pain. It is possible that a more localized biopsy specimen will be more specific for clarifying the condition of SFN. Patients with jaw pain and OFP consult their dentists for these symptoms and do not necessarily discuss them with their neurologists or primary care physicians unless specifically asked. Similarly, due to a lack of data on the characterization of this patient group, many patients with OFP do not undergo work-up for SFN and hence the data can be skewed due to more patients with typical length-dependent neuropathic symptoms in this cohort.
ConclusionsOFP and sensory and autonomic neuropathies can be overlapping conditions. The study shows a significant correlation between TMD and dysautonomia, which has not been studied before. Hence, patients presenting with concomitant TMD and dysautonomia can be further tested for SFN. This can further help us understand a correlation, if any, between idiopathic TMD/OFP conditions and SFN and further our understanding of the pathophysiology of these conditions. To further our understanding of the correlation between OFP/TMD conditions and SFN, more structured studies focusing on OFP, neuropathies, and dysautonomia will be needed. Presence of psychological comorbidities in these patients warrants a multidisciplinary team, to include neurologist, OFP specialist, and psychologist/psychiatrist in appropriate management of these patients. One cannot ignore the correlation between obesity and presence of OFP in this cohort. Well-designed studies to understand the relation between these two chronic conditions, obesity, and OFP, are needed.
AcknowledgmentsHarvard Catalyst consultation was used for biostatistics.
DisclosureThe authors report no conflicts of interest in this work.
References1. May A, Benoliel R, Imamura Y, et al. Orofacial pain for clinicians: a review of constant and attack-like facial pain syndromes. Cephalalgia. 2023;43(8):3331024231187160. doi:10.1177/03331024231187160
2. Häggman-Henrikson B, Liv P, Ilgunas A, et al. Increasing gender differences in the prevalence and chronification of orofacial pain in the population. Pain. 2020;161(8):1768–1775. doi:10.1097/j.pain.0000000000001872
3. Handa S, Keith DA, Abou-Ezzi J, Rosèn A. Neuropathic orofacial pain: characterization of different patient groups using theICOP first edition, in a tertiary level Orofacial Pain Clinic. Oral Surg Oral Med Oral Pathol Oral Radiol. 2021;132(6):653–661. doi:10.1016/j.oooo.2021.07.021
4. Orofacial T, Classification P. International Classification of Orofacial Pain, 1st edition (ICOP). Cephalalgia. 2020;40(2):129–221. doi:10.1177/0333102419893823
5. Rosén A, Lund B, Berge T. Addressing Non-Responding Chronic TMD Patients Experience from a Multidisciplinary Approach. J Otolaryngol Res. 2018;2018:1.
6. Breckons M, Shen J, Bunga J, Vale L, Durham J. DEEP Study: indirect and Out-of-pocket Costs of Persistent Orofacial Pain. J Dent Res. 2018;97(11):1200–1206. doi:10.1177/0022034518773310
7. Terkelsen AJ, Karlsson P, Lauria G, Freeman R, Finnerup NB, Jensen TS. The diagnostic challenge of small fibre neuropathy: clinical presentations, evaluations, and causes. Lancet Neurol. 2017;16(11):934–944. doi:10.1016/S1474-4422(17)30329-0
8. Khoshnoodi MA, Truelove S, Burakgazi A, Hoke A, Mammen AL, Polydefkis M. Longitudinal Assessment of Small Fiber Neuropathy: evidence of aNon-Length-Dependent Distal Axonopathy. JAMA Neurol. 2016;73(6):684–690. doi:10.1001/jamaneurol.2016.0057
9. Thaisetthawatkul P, Fernandes Filho JA, Herrmann DN. Autonomic evaluation is independent of somatic evaluation for small fiber neuropathy. J Neurol Sci. 2014;344(1–2):51–54. doi:10.1016/j.jns.2014.06.017
10. Lopate G, Streif E, Harms M, Weihl C, Pestronk A. Cramps and small-fiber neuropathy. Muscle Nerve. 2013;48(2):252–255. doi:10.1002/mus.23757
11. Hoeijmakers JG, Faber CG, Lauria G, Merkies IS, Waxman SG. Small-fibre neuropathies--advances in diagnosis, pathophysiology and management. Nat Rev Neurol. 2012;8(7):369–379. doi:10.1038/nrneurol.2012.97
12. Lauria G, Majorana A, Borgna M, et al. Trigeminal small-fiber sensory neuropathy causes burning mouth syndrome. Pain. 2005;115(3):332–337. doi:10.1016/j.pain.2005.03.028
13. Oaklander AL. The density of remaining nerve endings in human skin with and without postherpetic neuralgia after shingles. Pain. 2001;92(1–2):139–145. doi:10.1016/s0304-3959(00)00481-4
14. Penza P, Majorana A, Lombardi R, et al. “Burning tongue” and “burning tip”: the diagnostic challenge of the burning mouth syndrome. Clin J Pain. 2010;26(6):528–532. doi:10.1097/AJP.0b013e3181e15b83
15. Gemignani F, Bellanova MF, Saccani E, Pavesi G. Non-length-dependent small fiber neuropathy: not a matter of stockings and gloves. Muscle and Nerve. 2022;65(1):10–28. doi:10.1002/mus.27379
16. Oaklander AL, Klein MM. Evidence of small-fiber polyneuropathy in unexplained, juvenile-onset, widespread pain syndromes. Pediatrics. 2013;131(4):e1091–100. doi:10.1542/peds.2012-2597
17. Oaklander AL, Herzog ZD, Downs HM, Klein MM. Objective evidence that small-fiber polyneuropathy underlies some illnesses currently labeled as fibromyalgia. Pain. 2013;154(11):2310–2316. doi:10.1016/j.pain.2013.06.001
18. Zirpoli GR, Farhad K, Klein MC, Downs S, Klein MM, Oaklander AL. Initial validation of the Mass. General Neuropathy Exam Tool (MAGNET) for evaluation of distal small-fiber neuropathy. Muscle and Nerve. 2024;69(2):185–198. doi:10.1002/mus.28013
19. Maixner W, Fillingim RB, Williams DA, Smith SB, Slade GD. Overlapping Chronic Pain Conditions: implications for Diagnosis andClassification. J Pain. 2016;17(9 Suppl):T93–T107. doi:10.1016/j.jpain.2016.06.002
20. Veasley C, Clare D, Clauw DJ, et al. Impact of chronic overlapping pain conditions on public health and the urgent need for safe and effective treatment: 2015 analysis and policy recommendations. Chronic Pain Res. 2015;2015:1.
21. Diatchenko L, Anderson AD, Slade GD, et al. Three major haplotypes of the beta2 adrenergic receptor define psychological profile, blood pressure, and the risk for development of a common musculoskeletal pain disorder. Am J Med Genet B. 2006;141B(5):449–462. doi:10.1002/ajmg.b.30324
22. Peters MJH, Bakkers M, Merkies ISJ, Hoeijmakers JGJ, van Raak EPM, Faber CG. Incidence and prevalence of small-fiber neuropathy: a survey in the Netherlands. Neurology. 2013;81(15):1356–1360. doi:10.1212/WNL.0b013e3182a8236e
23. Devigili G, Cazzato D, Lauria G. Clinical diagnosis and management of small fiber neuropathy: an update on best practice. Expert Rev Neurother. 2020;20(9):967–980. doi:10.1080/14737175.2020.1794825
24. Grayston R, Czanner G, Elhadd K, et al. A systematic review and meta-analysis of the prevalence of small fiber pathology in fibromyalgia: implications for a new paradigm in fibromyalgia etiopathogenesis. Semin Arthritis Rheum. 2019;48(5):933–940. doi:10.1016/j.semarthrit.2018.08.003
25. Shoenfeld Y, Ryabkova VA, Scheibenbogen C, et al. Complex syndromes of chronic pain, fatigue and cognitive impairment linked to autoimmune dysautonomia and small fiber neuropathy. Clin Immunol. 2020;214:108384. doi:10.1016/j.clim.2020.108384
26. Mantyh WG, Dyck PJB, Dyck PJ, et al. Epidermal Nerve Fiber Quantification in Patients With Erythromelalgia. JAMA Dermatol. 2017;153(2):162–167. doi:10.1001/jamadermatol.2016.4404
27. Devigili G, Rinaldo S, Lombardi R, et al. Diagnostic criteria for small fibre neuropathy in clinical practice and research. Brain. 2019;142(12):3728–3736. doi:10.1093/brain/awz333
28. Durham J, McDonald C, Hutchinson L, Newton JL. Painful temporomandibular disorders are common in patients with postural orthostatic tachycardia syndrome and impact significantly upon quality of life. J Oral Facial PainHeadache. 2015;29(2):152–157. doi:10.11607/ofph.1396
29. Léonard G, Chalaye P, Goffaux P, Mathieu D, Gaumond I, Marchand S. Altered autonomic nervous system reactivity to pain in trigeminal neuralgia. Can J Neurol Sci. 2015;42(2):125–131. doi:10.1017/cjn.2015.10
30. Fillingim RB, Ohrbach R, Greenspan JD, et al. Psychological factors associated with development of TMD: the OPPERA prospective cohort study. J Pain. 2013;14(12):T75–T90. doi:10.1016/j.jpain.2013.06.009
31. Hitt HC, McMillen RC, Thornton-Neaves T, Koch K, Cosby AG. Comorbidity of obesity and pain in a general population: results from theSouthern Pain Prevalence Study. J Pain. 2007;8(5):430–436. doi:10.1016/j.jpain.2006.12.003
32. Rossi HL, Raj NR, Marquez de Prado B, et al. Trigeminal Pain Responses in Obese ob/ob Mice Are Modality-Specific. Neuroscience. 2019;415:121–134. doi:10.1016/j.neuroscience.2019.06.043
33. Rossi HL, Broadhurst KA, Luu ASK, et al. Abnormal trigeminal sensory processing in obese mice. Pain. 2016;157(1):235–246. doi:10.1097/j.pain.0000000000000355
留言 (0)