Christidis et al. The Journal of Headache and Pain 2014, 15:63

http://www.thejournalofheadacheandpain.com/content/15/1/63

Nikolaos Christidis1,2*, Isabell Kang3, Brian E Cairns3,4, Ujendra Kumar3, Xudong Dong3,5, Annika Rosn6,7, Sigvard Kopp1 and Malin Ernberg1,2

Abstract

Background: Previous studies have shown that 5-HT3-antagonists reduce muscle pain, but there are no studies that have investigated the expression of 5-HT3-receptors in human muscles. Also, tetrodotoxin resistant voltage gated sodium-channels (NaV) are involved in peripheral sensitization and found in trigeminal ganglion neurons innervating the rat masseter muscle. This study aimed to investigate the frequency of nerve fibers that express 5-HT3A-receptors alone and in combination with NaV1.8 sodium-channels in human muscles and to compare it between healthy pain-free men and women, the pain-free masseter and tibialis anterior muscles, and patients with myofascial temporomandibular disorders (TMD) and pain-free controls.

Methods: Three microbiopsies were obtained from the most bulky part of the tibialis and masseter muscles of seven and six healthy men and seven and six age-matched healthy women, respectively, while traditional open biopsies were obtained from the most painful spot of the masseter of five female patients and from a similar region of the masseter muscle of five healthy, age-matched women. The biopsies were processed by routine immunohistochemical methods. The biopsy sections were incubated with monoclonal antibodies against the specific axonal marker PGP 9.5, and polyclonal antibodies against the 5-HT3A-receptors and NaV1.8 sodium-channels.

Results: A similar percentage of nerve fibers in the healthy masseter (85.2%) and tibialis (88.7%) muscles expressed 5-HT3A-receptors. The expression of NaV1.8 by 5-HT3A positive nerve fibers associated with connective tissue was significantly higher than nerve fibers associated with myocytes (P < .001). In the patients, significantly more fibers per section were found with an average of 3.8 3 fibers per section in the masseter muscle compared to 2.7 0.2 in the healthy controls (P = .024). Further, the frequency of nerve fibers that co-expressed NaV1.8 and 5-HT3A receptors was significantly higher in patients (42.6%) compared to healthy controls (12.0%) (P < .001).

Conclusions: This study showed that the 5-HT3A-receptor is highly expressed in human masseter and tibialis muscles and that there are more nerve fibers that express 5-HT3A-receptors in the masseter of women with myofascial TMD compared to healthy women. These findings indicate that 5-HT3-receptors might be up-regulated in myofascial TMD and could serve as potential biomarkers of chronic muscle pain.

Keywords: Muscle biopsy; Human subjects; Myofascial TMD; 5-HT3-receptor; NaV1.8 sodium channel

* Correspondence: mailto:[email protected]

Web End [email protected]

1Orofacial Pain and Jaw Function, Department of Dental Medicine, Karolinska Institutet, Huddinge, Sweden

2Scandinavian Center for Orofacial Neuroscience (SCON), Stockholm, Sweden Full list of author information is available at the end of the article

2014 Christidis et al.; licensee Springer. This is an Open Access article distributed under the terms of the Creative Commons

Attribution License (http://creativecommons.org/licenses/by/4.0

Web End =http://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited.

RESEARCH ARTICLE Open Access

Expression of 5-HT3 receptors and TTX resistant sodium channels (NaV1.8) on muscle nerve fibers in pain-free humans and patients with chronic myofascial temporomandibular disorders

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 2 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

Background

Serotonin (5-HT) is an important biogenic amine that fulfills the role of a neurotransmitter and neuromodulator, and is an important mediator of pain both peripherally and centrally [1,2]. Several studies have shown that 5-HT concentrations are significantly elevated in painful muscles of patients with chronic myalgia [3-6]. In the periphery, 5-HT has been shown to excite and sensitize nociceptors, and in humans to cause muscle pain and sensitivity [7]. Excitation of nociceptors by 5-HT may be due to either a direct effect, such as activation of the 5-HT3 receptor, or an indirect effect, which may involve the release of other algogens, such as substance P or glutamate [8,9]. In humans, evidence suggests that 5-HT activates the 5-HT3-receptor to mediate muscle pain and sensitivity to mechanical stimulation [7,10-14].

Five subunits of the 5-HT3-receptor have been identified (5-HT3A 5-HT3E). The 5-HT3A subunit forms a complete receptor, while the other subunits can only form functional receptor complexes together with the 5-HT3A subunit [15-17]. Results from some studies indicate that intramuscular injections of 5-HT3 antagonists may be effective for treatment of various muscular pain conditions [18-20]. The 5-HT3 antagonist granisetron has been shown to reduce pain and allodynia induced by 5-HT or hypertonic saline [10,13] and also to increase the pressure pain threshold (PPT) over healthy muscles in human experimental studies [10,11,21]. In a recent study, we reported that approximately 45-50% of the muscle nerve fibers of both healthy humans and rat expressed the NMDA receptor subunit 2B [22] but the expression of 5-HT3-receptors in human muscles has not yet been investigated nor if the frequency is altered in painful muscles. Hence, it is not clear if the pain-reducing effect of these 5-HT3 antagonists is only due to blocking of 5-HT3 receptors or if they act on other receptors as well.

The tetrodotoxin (TTX) resistant sodium channels (NaVs) have been shown to be highly expressed in small neurons of the dorsal root ganglia (DRG) in both human and animal studies considered to be probable nociceptors [23]. The NaV1.8 channel has also been found in the soma of small diameter sensory C and A neurons [24] which have been shown to be involved in nociception in models of neuropathic and inflammatory pain [25]. One study reported that the NaV1.8 channel is present in 86%

of the muscle sensory afferent fibers, which makes it a useful marker of putative muscle nociceptors [26], and recently it has been found in trigeminal ganglion neurons innervating the rat masseter muscle [27]. Taken together, this evidence suggests that NaV1.8 channel mainly found in the peripheral sensory neurons and their expression on nerve fibers provides a method to identify putatively nociceptive afferent fibers [24,28]. The NaV1.8 has

been shown to participate in nociception and peripheral sensitization, and therefore is thought to be an important for chronic pain [23-25,29,30]. It has further been shown that inflammatory mediators, such as serotonin, increase the excitability of sensory neurons by modulating the NaV1.8 [31-33]. Therefore, NaV1.8 is particularly interesting both as a marker of putative nociceptive afferent fibers and as an additional target/mechanism to explain the analgesic effects of local administration of the 5-HT3 receptor antagonists [10,18-21].

The purpose of this study was to investigate the expression of 5-HT3A-receptors and NaV1.8 sodium channels in nerve fibers of human masseter and tibialis muscles, since results from both animal and human experimental studies suggest that 5-HT3 receptor antagonists reduce musculoskeletal pain and hyperalgesia [18-20]. Further, it is not known if the 5-HT3 receptor is expressed in painful muscle tissues of humans. If so, it could offer an important target for novel treatment approaches for these patients and provide important information about the pathophysiology of muscle pain especially in the temporomandibular region. Therefore, the study also aimed to investigate the frequency of nerve fibers that co-express the 5-HT3A-receptors and NaV1.8 sodium channels and to compare the frequency 1) between healthy pain-free men and women; 2) between patients with myofascial temporomandibular disorders (TMD) and pain-free, healthy, sex- and age-matched controls; and 3) between the masseter and tibialis anterior muscles (a muscle seldom affected by chronic pain) of healthy men and women. An additional aim of the study was to investigate if a minimal invasive microbiopsy technique is equivalent to the traditional open biopsy technique for immunohistochemical analyses of receptor expression in human muscles.

Methods

The methods and selection of participants were approved by the regional ethical review board in Stockholm, Sweden, (2007/2:6). All participants were above 20 years of age and the study followed the principles for medical research according to the guidelines of the Declaration of Helsinki as well as the Good Clinical Practice guidelines.

At a separate visit the participants were screened for trial suitability with a clinical examination performed in accordance with the Research Diagnostic Criteria for TMD (RDC/TMD [34]) after information about the study protocol. The participants received both written as well as verbal information and gave their verbal and written consent.

ParticipantsTwenty three healthy volunteers and five patients with myofascial TMD were included in the study. The patients were recruited from patients referred to the

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 3 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

section for Orofacial Pain and Jaw function, Department of Dental Medicine, Karolinska Institutet, Huddinge, Sweden, while the healthy volunteers were recruited from colleagues at the Department of Dental Medicine. The biopsy procedure took place at the Department of Dental Medicine, Karolinska Institutet, Huddinge, Sweden at the section for Orofacial Pain and Jaw Function as well as at the section of Oral and Maxillofacial Surgery.

The distribution of the participants, their age and the duration of the local pain are shown in Table 1.

Inclusion criteriaThe inclusion criteria for the healthy volunteers were age over 20 years and good general health.

The inclusion criteria for the patients were age over 20 years, a diagnosis of myofascial pain according to RDC/TMD criteria and pain, upon digital palpation, of at least one of the masseter muscles.

Exclusion criteriaThe exclusion criteria for both the healthy volunteers and the patients were diagnosis of: a) systemic muscular or joint diseases (e.g. fibromyalgia, rheumatoid arthritis, ankylosing spondylitis, psoriatic arthritis); b) whiplash associated disorder; c) neuropathic pain or neurological disorders (e.g. myasthenia gravis, craniomandibular dystonia),

or report of: d) pain of dental origin; e) pregnancy; f) frequent use of muscle relaxants; and g) use of analgesic or anti-inflammatory medication during the 24 hours preceding biopsy.

An additional exclusion criterion for the healthy volunteers was facial pain or palpatory tenderness of the masseter or tibialis muscles.

Biopsy-proceduresMicrobiopsiesMicrobiopsies were obtained from the masseter and tibialis anterior muscles from seven healthy men and seven age-matched healthy women. During the analysis process two biopsies from the masseter muscle were misplaced (from one man and one woman). The microbiopsies were taken through the skin overlaying the most prominent part of the masseter muscle and the tibialis anterior muscle. This procedure was performed under skin surface anesthesia using a prefabricated anesthetic patch (EMLA Patch, 25 mg lidocaine and 25 mg prilocaine, AstraZeneca, Sdertlje, Sweden) that was placed over the area to be penetrated, for a duration of 30 min. A disposable MonoptyBard biopsy instrument with a penetration depth of 11 mm and a diameter of 18G was used for the masseter muscle, while for the tibialis anterior muscle a diameter of 16G was used. The biopsy instrument was

Table 1 The distribution of the age-matched participants divided by biopsy technique and sex

Microbiopsy Traditional open biopsy Healthy -Masseter Healthy - Tibialis Healthy Patients

Number of participants

All 12 14 5 5 Men 6 7 0 0 Women 6 7 5 5 AgeAll 34.6 (10.1) 37.4 (11.8) 52.0 (8.5) 50.4 (8.2) Men 34.8 (9.9) 37.7 (11.9) - -Women 34.3 (11.2) 37.1 (12.6) 52.0 (8.5) 50.4 (8.2) Duration of painMen -Women 3.0 (2.6) Intensity of painMen -Women 5.0 (1.25) Co-morbid headacheMen -Women 5

The table displays the number (n) of participants, their mean (SD) age (years), median (IQR) duration of pain (years), current median (IQR) intensity of pain (NRS), as well as number (n) of patients with co-morbid headache. The 12 participants in the microbiopsy masseter group are the same individuals as the 12 out of the 14 in the tibialis group.

NRS = Numeric rating scale (010).

IQR = Interquartile range (75 percentile minus 25 percentile).

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 4 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

guided with a BardTruGuide coaxial needle (BARD Norden, Helsingborg, Sweden), that was inserted to a depth of 10 mm. This biopsy system is automated and of a type that has been proven to be effective i.e. for the diagnosis of musculoskeletal sarcomas [35].

Three microbiopsies were taken from each muscle in order to ensure that sufficient muscle tissue was obtained. The coaxial needle was inserted along the near long axis of the muscles until the fascia was penetrated and the biopsy instrument was then inserted through the coaxial needle. By pressing the trigger button the piston of the needle collected a piece of the muscle with a size of approximately 0.12 cm * 1.1 cm in the masseter and 0.14 cm * 1.1 cm in the tibialis anterior. The biopsy instrument was then slid out from the coaxial needle while the latter was maintained in place, thus avoiding repeated skin punctures. The muscle section was removed from the biopsy instrument using a sterile probe, and the biopsy instrument was rinsed with isotonic saline. This procedure was repeated twice. Each time the biopsy instrument was rotated 45 so that the microbiopsy would be taken from a new portion of the muscle.

Traditional open biopsiesTraditional open biopsies were obtained intra-orally from the masseter muscle of five myofascial TMD patients (all women) and from five healthy, age-matched women (not participating in the microbiopsy part). In the patients the most painful spot of the masseter muscle was aimed at, while in the healthy volunteers the spot selected coincided with the most painful spot in the patient that they were to be compared with.

After anesthesia with 1 mL lidocaine-adrenalin (20 mg/mL + 12.5 g/mL) the oral mucosa was incised with a scalpel to expose the masseter muscle. The selected section was then cut out and removed from the muscle with a forceps. Two vicryl-sutures were placed over the incision and removed after one week.

The biopsies from the healthy volunteers were also used to validate the minimal invasive microbiopsy technique. This was done by investigating if the muscle sections obtained with the two different techniques were equivalent regarding the weight and size of the obtained biopsies, the amount of surrounding tissue in the biopsies, receptor expression, the subjective post-surgical discomfort and the participants experience of the procedures as well as the area of the wound.

Analysis of the biopsiesBlinding of samplesThe microbiopsies were obtained and coded by NC (DDS, PhD, specialist in orofacial pain and jaw function), the human traditional open biopsies were obtained by AR (DDS, PhD, Professor, specialist in oral and maxillofacial surgery)

and coded by NC. The codes were not revealed to the person (IK) analyzing the samples.

ImmunohistochemistryBoth the microbiopsies and the open biopsies were fixed with 4% paraformaldehyde at 4C over-night, rinsed in phosphate-buffered saline (PBS), and then dehydrated, embedded in paraffin and sectioned at a thickness of 10 m. The sections were mounted on glass slides, stored at 37C over-night, dipped into xylene to remove the paraffin and rehydrated by being rinsed in ethanol (100%, 90% and 70%). The sections were then boiled in 10 mM (pH 6.0) citrate buffer for 10 minutes and rinsed as well as stored in PBS. Subsequently, the sections were incubated in normal goat serum for 1 hour, and then for 24 hours with primary antibodies against the specific axonal marker PGP 9.5 (pre-diluted mouse anti-human monoclonal antibody, ABCAM Inc, Cambridge, England; ab75447) and antibodies against the 5-HT3A receptors (goat polyclonal anti-human antibody, 1:100, Santa Cruz Biotechnology Inc, Santa Cruz, CA, USA; sc-19150) and NaV1.8 sodium channels (rabbit anti-human polyclonal antibody, 1:200, ABCAM Inc, Cambridge, England; ab66743). The specificity of the antibodies has been previously confirmed by pre-adsorption [36,37]. Sections were rinsed with PBS and incubated with fluorescent secondary antibodies (Alexa 488 donkey-anti-goat, 1:700 for 5HT3A, Alexa 555 donkey-anti-mouse, 1:700 for PGP9.5, and Alexa 633 donkey-anti-rabbit, 1:700 for NaV1.8, Vancouver, Canada). Sections were examined with a Leica TCS SPE Confocal Microscope (Leica microsystems, Wetzlar, Germany) and images were captured for analysis using a Leica scanner attached to the microscope (Figure 1). Omission of the primary antibodies did not result in specific staining of tested sections.

Analyzes of the muscle biopsies and criteria for delineation of one nerve fiberFrom each muscle biopsy a median of 4 (IQR 1) sections were analyzed.

Labeling was considered positive when the intensity of the fluorescent signal exceeded the 95% confidence interval of the mean background intensity. The minimum length of a labeled fiber accepted was 1 m.

When presenting the localization of the nerve fibers they were divided into two groups, either associated with myocytes or with connective tissue. When the PGP 9.5 positive nerve fibers were in close vicinity to myocytes, i.e. long, tubular well-defined cells, they were placed in the group associated with myocytes (arrows in Figure 2). When the fibers were in irregular tissue surrounding the myocytes they were grouped as associated with connective tissue (double arrows in Figure 2).

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 5 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

Figure 1 Example of high power (40 x) photomicrographs for a masseter section from one female patient with myofascial TMD and a

healthy age- and sex-matched pain-free volunteer. The fibers shown are positively labelled for PGP 9.5 (A), 5-HT3A (B), and NaV1.8 (C). (D) is

the composite image. Calibration bar: 100 m.

The expression of the receptors was analyzed by assessing the amount of PGP 9.5 labeled nerve fibers that co-expressed the 5-HT3A receptor alone or in combination with the NaV1.8 sodium channel. PGP 9.5 positive nerve fibers that co-expressed both NaV1.8 and 5-HT3A receptors were considered as putative nociceptors. The image processing and analysis program ImageJ, (Image Processing

and Analysis in Java; National Institutes of Health, USA) was used.

StatisticsFor data and statistical analyses the SigmaStat software version 3.10 (Systat software Inc., San Jose, CA, USA) was used. Data concerning the participants are expressed

Figure 2 A low power (10 x) (in A) and a high power (40 x) (in B) image of the same section of a masseter muscle (microbiopsy from a

pain-free volunteer). A. The arrows indicate individual muscle fascicles composed of myocytes separated by connective tissue. B. A higher

power (40 x, rounded square in A) image of PGP 9.5 labelling with examples of fibers associated with myocytes (arrows) and connective tissue

(double arrows). The insets show examples of a PGP 9.5 positive fiber associated with a myocyte (i) and with connective tissue (ii). Calibration bar

A: 100 m, B: 25 m.

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 6 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

as mean (SD), except for pain characteristics that are expressed with median and interquartile range (IQR) since they were either not normally distributed or assessed on an interval scale. Data regarding receptor expression was normally distributed and was not transformed. The frequencies of receptor expression are presented as mean (SEM). To test for significant differences regarding the frequency of expression of the 5-HT3A

receptors and the NaV1.8 sodium channels as well as for significant differences between biopsy techniques Students t-tests were used. For all tests the level of significance was set to P < .05.

Results

Receptor expressionMicrobiopsiesIn microbiopsies of healthy volunteers PGP 9.5 immuno-reactive fibers were identified in sections from 12 subjects (6 men and 6 women) of the masseter muscle and from 14 subjects (7 men and 7 women) of the tibialis muscle. In the masseter muscle an average of 8.2 1.2 (mean SEM) PGP 9.5 immunoreactive fibers per section was found and in the tibialis muscle an average of7.8 1.3 fibers per section was found. Most fibers that showed PGP 9.5 immunoreactivity were associated with myocytes (masseter = 68.4%, tibialis = 87.8%).

The frequency of PGP 9.5 fibers expressing the 5-HT3A receptor alone or in combination with the NaV1.8 sodium channel are presented in Table 2, mean frequencies for antibody labelling of PGP 9.5 immunoreactive fibers are shown in Figure 3. Both in the masseter and tibialis muscles, the majority of the PGP 9.5 positive fibers expressed 5-HT3A receptors. In the tibialis muscle a significantly greater number of these fibers were

associated with myocytes than with connective tissue (Table 2).

In the masseter and tibialis muscles respectively, 8.2% and 9.6% of PGP 9.5 positive fibers co-expressed NaV1.8 and 5-HT3A. The vast majority of these fibers were found in connective tissue both in the masseter and in the tibialis muscles.

Sex differencesIn the masseter there was no significant difference in the mean nerve fiber density when men were compared with women. There was no significant difference in the expression of 5-HT3A positive fibers associated with myocytes or connective tissue between sexes (Table 3).

There was no significant difference in the mean density of fibers in the tibialis when men were compared with women. Likewise, there was no significant difference in the expression of 5-HT3A positive fibers associated with myocytes or with connective tissue (Table 3).

Traditional biopsies of the masseter muscleIn the traditional masseter biopsies of healthy female volunteers (n = 5) an average of 2.7 0.2 PGP 9.5 immunoreactive nerve fibers per section was found.

The vast majority of the PGP 9.5 positive fibers expressed 5-HT3A receptors. Similar to what was found for the microbiopsies of the masseter muscle, the majority of nerve fibers were associated with myocytes (Table 2).12.0% of the PGP 9.5 positive fibers were found to co-express NaV1.8 and 5-HT3A receptors. A significantly greater number of nerve fibers that co-expressed NaV1.8 and 5-HT3A was associated with connective tissue than with myocytes (Table 2).

Table 2 Presentation of the frequency (%) and location of the positive PGP 9.5 immunoreactive fibers

Fibers expressing 5-HT3A Fibers expressing 5-HT3A and NaV1.8 Percentage of

PGP 9.5 fibers

Location of positive fibers Percentage of

PGP 9.5 fibers

Location of positive fibers

Myocytes Connective tissue Myocytes Connective tissue

Traditional biopsies

Masseter musclePatients (n = 5) 98.3% 65.6% 34.4% 42.6%### 17.8% 82.2%*** Healthy (n = 5) 96.0% 62.5% 37.5% 12.0% 12.5% 87.5%*** MicrobiopsiesMasseter muscleHealthy (n = 12) 85.2% 70.5% 29.5% 8.2% 11.8% 88.2%*** Tibialis muscleHealthy (n = 14) 88.7% 86.0% 14.0%* 9.6% 0% 100.0%***

The table shows the frequency of the PGP 9.5 immunoreactive fibers expressing the 5-HT3A-receptor alone or in combination with the NaV1.8 sodium channel as well as the location of the positive fibers within the muscle tissue and their distribution (in association with myocytes or in the connective tissue surrounding the myocytes).*Significantly lower frequency of positive fibers in connective tissue compared to myocytes (P < .011, paired t-test).***Significantly higher frequency of positive fibers in connective tissue compared to in myocytes (P < .001, paired t-test).

###Significantly greater frequency in patients than in healthy individuals (P < .001, unpaired t-test).

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 7 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

Figure 3 A comparison showing the different mean frequencies for antibody labelling on PGP 9.5 immunoreactive fibers (5-HT3A; both 5-HT3A and NaV1.8) in the masseter and tibialis tissues. There were no significant differences in the frequency of fibers that expressed 5-HT3A

or both 5-HT3A and NaV1.8, when the two muscles were compared (P > .05, Students t-test). Each bar represents the average from all the sections

obtained from each muscle type. The error bars depict standard error of the mean.

In the masseter muscle of female patients (n = 5) an average of 3.8 3 PGP 9.5 positive fibers per section was found. Virtually all PGP 9.5 positive fibers expressed 5-HT3A receptors. Similar to healthy individuals, the majority of these nerve fibers were associated with myocytes.42.6% of the PGP 9.5 positive fibers in the masseter of the patients co-expressed NaV1.8 and 5-HT3A receptors.

There was a significantly higher co-expression of NaV1.8 and 5-HT3A positive fibers that were associated with connective tissue than with myocytes (Table 2).

Differences between TMD patients and pain-free controls The total number of PGP 9.5 positive fibers per section that expressed 5-HT3A receptors was significantly higher in female patients (3.79 0.75) compared to healthy females (2.37 0.58) (P = .010). Also the frequency of PGP

9.5 positive fibers that co-expressed NaV1.8 and 5-HT3A receptors was significantly higher than that found in healthy women (Table 2; and as an example see Figure 1).

Differences between the biopsy techniquesBoth techniques provided an adequate muscle section. However, the muscle sections obtained with the micro-biopsy technique were significantly smaller in volume and in weight as well as in the area of the wound at the entrance to the muscle. Further, the microbiopsies caused less discomfort and fewer visits for the individual undergoing the procedure (Table 4).

The number of PGP 9.5 positive fibers per section was significantly higher in the microbiopsies of healthy women than in traditional biopsies from the healthy

Table 3 Presentation of the mean (SD) nerve fiber density and their distribution within the sections

Nerve fiber densityFibers per section (n=) Location (%) of positive fibers

Myocytes Connective tissue Men Women Men Women Men Women

Microbiopsies

Masseter muscleHealthy (n = 12) 6.7 1.8 5.6 1.5 76 15% 78 20% 45 20% 40 24% Tibialis muscleHealthy (n = 14) 6.7 1.9 8.9 1.9 95 2% 77 13% 26 17% 38 17%

The table presents the mean nerve fiber density (i.e. fibers per section), the percentage difference of positive fibers within the muscle tissue, and the distribution (either in association with myocytes or in the connective tissue surrounding the myocytes).

There are microbiopsies from the masseter muscle from six men and six women, while there are microbiopsies from seven men and seven women from the tibialis muscle.

There were no significant differences.

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 8 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

Table 4 Comparison of the two techniques used for obtaining masseter biopsies from healthy volunteers

Microbiopsies (n = 18) Traditional biopsies (n = 10)

Mean weight of each muscle section 19.8 (2.5) mg*** 58.4 (9.6) mg

Mean volume of each muscle section 13.0 (1.6) mm3*** 64.4 (9.9) mm3 Surrounding tissues No YesType of tissue Parotid gland (20%)

Fat cells (30%)

Adequate muscle section 100% 100% Number of PGP 9.5 positive fibers

per section

8.2 1.2* 2.7 0.2

Area of wound 1 (0.04) mm2*** 10 (0.7) mm2Post-surgical discomfort 3 (1) days 8 (2) daysType of discomfort Palpatory tenderness over the belly of the masseter (100%) Palpatory tenderness over the belly of the

masseter muscle (100%)

Bleeding (6%) Limited jaw function (10%)

Chewing difficulties (50%)

Discomfort from sutures (100%)

Extra visit to remove sutures (100%)

Differences are presented as mean (SD) values.*P < .05, unpaired t-test, ***P < .001, unpaired t-test.

women (Table 4), but there were no significant differences in the receptor expression between the two biopsy techniques. In the microbiopsy group, 70.5% of the fibers associated with myocytes expressed 5-HT3A receptors while the corresponding number was 62.5% in the traditional biopsy group. Further 29.5% of the fibers associated with connective tissue fibers expressed 5-HT3A

receptors in the microbiopsy group, whereas the corresponding number was 37.5% in the traditional biopsy group (Table 2).

Discussion

Main findingsThe main findings of this study were that the 5-HT3A re

ceptor is highly expressed in human masseter and tibialis muscle tissue, but that there were no differences in expression due to sex. Further, there were more immuno-reactive nerve fibers expressing 5-HT3 receptors and

NaV1.8 sodium channels in the masseter muscle of female patients with myofascial TMD compared to healthy female controls. These findings indicate that 5-HT3 receptors might be up-regulated in myofascial TMD and may therefore play a role in pain transmission, hence providing the 5-HT3-receptor as a target for future therapeutics or as a potential biomarker of chronic muscle pain.

Secondarily, the results from this study indicate that the microbiopsy technique provided sufficient muscle tissue, less discomfort and post-surgical pain than the traditional biopsy technique. Therefore, the microbiopsy technique can be regarded as a valid biopsy method for

immunohistochemical analyses of muscle tissue, and may, thus, be preferred to traditional open biopsies in future studies or even as a diagnostic tool.

Receptor expressionThe immunohistochemical analysis of the muscle sections indicates that the 5-HT3A receptor is highly expressed by human masseter and tibialis anterior muscle nerve fibers. To our knowledge there are no other studies that have studied the expression of the 5-HT3 receptor in human muscle tissues. A recent study did show that the NMDA receptor is also expressed by masseter muscle nerve fibers (45-50%) in humans and rats [22]. However, results from animal studies regarding the expression of the 5-HT3 receptor in trigeminal and dorsal root ganglion neurons [7,38] are consistent with the present study. It is well established that the NaV1.8 sodium channels play an important role in nociception and chronic pain when found on small unmyelinated and thinly myelinated sensory neurons [24,25,29,30,39] since they contribute to action potentials in sensory neurons [28,39,40] and are involved in peripheral sensitization [23]. They have further also been found in large diameter sensory neurons in human pain states [41], as well as large diameter fibers in mouse [42] and rat [26,43]muscle afferent neurons. Hence, this TTX resistant sodium channel is not just limited to small diameter nerve fibers [44]. Inflammation has been shown to enhance nociceptive signaling by the NaV1.8 sodium channels [31,44-46], in part, through release of inflammatory mediators, such as 5-HT and prostaglandin E2, which directly increase NaV1.8 mediated currents [31,47].

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 9 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

Also, 5-HT is known to participate in pain mediation at the peripheral level, acting on the 5-HT3 receptors, which mainly appear on afferent nociceptive sensory, autonomic and enteric neurons [16]. Given this, one can assume that the NaV1.8 positive fibers are sensory neurons with a potential nociceptive function, consequently implying that the muscle nerve fibers that co-express the 5-HT3A receptors and NaV1.8 sodium channels are most probably nociceptors.

Noteworthy is the significantly higher average of fibers per section in the masseter muscle of patients with myofascial TMD, which could indicate a proliferation of nerve fibers in the painful muscle tissue. There is some evidence that hyper-innervation of the tendon with putative nociceptive fibers occurs in Achilles tendinosis [48,49]. The larger number of fibers in tender regions of the masseter muscle of TMD patients found in this study could indicate an up-regulation of 5-HT3 receptors. This finding may explain previous findings that a local injection of the 5-HT3 receptor antagonist granisetron was effective in decreasing muscle sensitivity in patients with localized myalgia [21] and fibromyalgia [50].

The majority of the 5-HT3A and NaV1.8 positive fibers in the masseter muscle were found in the connective tissue, which suggests that masticatory muscle pain may emanate primarily from the connective tissue. This theory is based on the findings from the muscle sections where both the patients and healthy subjects had significantly more NaV1.8 positive nerve fibers in connective tissue compared to fibers associated with myocytes. The elevated levels of serotonin in the masseter muscle in patients with myofascial TMD [3] and the very high expression of 5-HT3A and NaV1.8 positive fibers on sensory nerves associated with connective tissue, shown in this study, support the theory that the muscle nociceptors in painful muscles could be sensitized by serotonin and hence that serotonin may have an important role in myofascial TMD.

Apart from pain mediation, the 5-HT3 receptors are involved in many events in the human body. Centrally they play an important role in psychosis, anxiety, cognition and eating disorders [51], but also in motor system function. A recent study showed that activation of the 5-HT3 receptor induced rhythmic movements of the hindlimbs in mice [52]. In the periphery they have a well-known role in emetic pathways [53] and they have a role in the intestinal tone, activating colonic migrating motor complex, i.e. muscular motor activity [54]. PGP 9.5 labels both small and large diameter myelinated fibers[55] and NaV1.8 is a marker of small diameter thinly myelinated nociceptive fibers [44]. With this in mind, as the majority of the 5-HT3A positive muscle nerve fibers were located near myocytes and did not co-express NaV1.8, our findings imply that the 5-HT3A positive fibers

in association with the myocytes are likely either proprioceptive muscle spindle afferent fibers or motor axons [56].

Comparison of the biopsy techniquesThe results of this study indicate that the microbiopsy technique provided sufficient muscle tissue for immunohistochemistry and led to less discomfort and post-surgical pain as well as fewer visits than the traditional biopsy technique. This is in agreement with a previous study comparing the microbiopsy technique with the traditional open biopsy technique in the vastus lateralis of the quadriceps femoris muscle [57]. Further, the microbiopsy technique seems to be more precise, since by using the BardTruGuide coaxial needle, the surgeon is more likely to remove tissue from the exact region of interest without damaging the surrounding tissue [35]. It was also shown that the muscle sections from the micro-biopsies contained less of the surrounding tissues, such as parts of the salivary glands than traditional open biopsies (Table 4). Taken together this shows that the microbiopsy technique is a valid biopsy method for immunohistochemical analyses of muscle tissue and hence, may be preferred to traditional open biopsies in future studies or even as a diagnostic tool.

Differences due to sex or anatomical localizationIn contrast to a previous study [7] indicating that the expression of 5-HT3 receptors by trigeminal ganglion neurons innervating the masseter muscle was higher in female rats, this study showed no significant difference in the expression of 5-HT3A receptors in the masseter or tibialis muscles, when men and women were compared.

In previous studies, women reported more pain than men when serotonin was injected into the masseter muscle [13], and a larger pain area when hypertonic saline was injected [10]. Based on those studies one could have expected a significant sex difference with a larger amount of nerve fibers co-expressing 5-HT3A receptors and NaV1.8 sodium channels in women. Further, a previous human experimental study showed that systemic administration of the 5-HT3 receptor antagonist granisetron increased the PPT over the tibialis anterior muscle in men but not in women [11]. As a possible explanation for this difference could have been that the number of receptors differs between men and women, however, the findings of the present study do not support this explanation. It should be noted that a limitation of this study is the small sample size (67 individuals of each sex), which may have been insufficient to permit identification of sex-related differences in 5-HT3A receptor expression.

There was a difference between the two skeletal muscles since a majority of the fibers co-expressing 5-HT3A

receptors and NaV1.8 sodium channels were found in the connective tissue in the masseter muscle while in

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 10 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

the tibialis muscle these fibers were found to be associated with myocytes. The tibialis muscle is rarely exposed to chronic pain in contrast to the masseter muscle and is further innervated by the deep peroneal nerve which major role is to contract the muscle fibers in order to dorsiflex and invert the foot [58]. In contrast to the tibialis anterior muscle, the masseter muscle expressed a larger amount of putatively nociceptive nerve fibers in the connective tissue. This is an interesting difference between muscles that could be a consequence of the different innervation with either trigeminal branches (masseter muscle) or spinal branches (tibialis muscle) and functionality of the nerves regarding motor and sensory functions [58]. Therefore, the larger amount of putatively nociceptive nerve fibers in the connective tissue of the masseter muscle and the difference in innervation might partly explain the more frequent presence of chronic myalgia in the masseter muscle.

Study limitationsOne limitation of the study is, as mentioned, the small sample size which might have affected the outcome regarding sex-related differences. Another possible limitation of the study is the exclusion criterion use of analgesic or anti-inflammatory medication during the 24 hours preceding the biopsy. This criterion was primarily in order to avoid any risk of including a patient with myofascial TMD among the healthy participants. However, 24 hours is a short wash-out period for NSAIDs which could have affected the biopsy procedure negatively, for example through increased bleeding, since the use of NSAIDs might impair the thrombocyte aggregation for up to 810 days. Use of NSAID might also have suppressed receptor expression. If so, it is likely that patients with myfascial TMD would have been affected more and in that case the difference in frequency would be even greater than found in the current study. The storage of the biopsies in paraffin could be another possible limitation since this technique might blunt the antigenicity of the samples, which may make it more difficult to detect the receptors. In future studies the muscle biopsies are suggested to be frozen immediately in 80C.

Conclusions

This study showed that the 5-HT3A receptor is highly expressed by human masseter and tibialis muscle nerve fibers. Further, a greater number of putative nociceptors were found to express the 5-HT3 in the masseter muscle of female patients with myofascial TMD compared to healthy female controls, which suggests that 5-HT3 receptors might be up-regulated in myofascial TMD. This finding could support the use of 5-HT3 receptor expression in muscle biopsies as a biomarker of chronic masticatory muscle pain.

AbbreviationsTMD: Temporomandibular disorders; 5-HT: 5-hydroxytryptamine serotonin; TTX: Tetrodotoxin; NaVs: Sodium channel; RDC/TMD: Research diagnostic criteria for temporomandibular disorders; PBS: Phosphate-buffered saline.

Competing interestsThe authors declare that they have no competing interests.

Authors contributionsNC, contributed in the design of the study, by collecting the material (microbiopsies), in the statistical analysis, and as the main author of the manuscript. IK contributed in the analysis of the material and in the result section of the manuscript. BEC, contributed in the design of the study, in the analysis of the material, in the statistical analysis, and in the manuscript in general. UK, contributed in the analysis of the material and in the discussion section of the manuscript. XD, contributed in the analysis of the material and in the discussion section of the manuscript. AR, contributed by collecting the material (traditional biopsies) and in the discussion section of the manuscript. SK, contributed in the design of the study and in the result and discussion section of the manuscript. ME, contributed in the design of the study, in the statistical analysis, and in the manuscript in general. All authors read and approved the final manuscript.

Author details

1Orofacial Pain and Jaw Function, Department of Dental Medicine, Karolinska Institutet, Huddinge, Sweden. 2Scandinavian Center for Orofacial Neuroscience (SCON), Stockholm, Sweden. 3Faculty of Pharmaceutical Sciences, University of British Columbia, Vancouver, Canada. 4Center for Sensory-Motor Interaction, Aalborg University, Aalborg, Denmark. 5College of Stomatology, Tianjin Medical University, Tianjin 300070, P. R. China. 6Oral and Maxillofacial Surgery, Department of Dental Medicine, Karolinska Institutet, Huddinge, Sweden. 7Oral and Maxillofacial Surgery, Department of Clinical Dentistry, University in Bergen, Bergen, Norway.

Received: 12 August 2014 Accepted: 8 September 2014 Published: 26 September 2014

References1. Zeitz KP, Guy N, Malmberg AB, Dirajlal S, Martin WJ, Sun L, Bonhaus DW, Stucky CL, Julius D, Basbaum AI (2002) The 5-HT3 subtype of serotonin receptor contributes to nociceptive processing via a novel subset of myelinated and unmyelinated nociceptors. J Neurosci 22(3):10101019

2. Fiebich BL, Akundi RS, Seidel M, Geyer V, Haus U, Muller W, Stratz T, Candelario-Jalil E (2004) Expression of 5-HT3A receptors in cells of the immune system. Scand J Rheumatol Suppl 119:911

3. Ernberg M, Hedenberg-Magnusson B, Alstergren P, Kopp S (1999) The level of serotonin in the superficial masseter muscle in relation to local pain and allodynia. Life Sci 65(3):313325

4. Ghafouri B, Larsson BK, Sjors A, Leandersson P, Gerdle BU (2010) Interstitial concentration of serotonin is increased in myalgic human trapezius muscle during rest, repetitive work and mental stress - an in vivo microdialysis study. Scand J Clin Lab Invest 70(7):478486. doi:10.3109/00365513.2010.511257

5. Rosendal L, Larsson B, Kristiansen J, Peolsson M, Sogaard K, Kjaer M, Sorensen J, Gerdle B (2004) Increase in muscle nociceptive substances and anaerobic metabolism in patients with trapezius myalgia: microdialysis in rest and during exercise. Pain 112(3):324334. doi:10.1016/j.pain.2004.09.017

6. Shah JP, Phillips TM, Danoff JV, Gerber LH (2005) An in vivo microanalytical technique for measuring the local biochemical milieu of human skeletal muscle. J Appl Physiol 99(5):19771984, doi:10.1152/japplphysiol.00419.2005

7. Sung D, Dong X, Ernberg M, Kumar U, Cairns BE (2008) Serotonin (5-HT) excites rat masticatory muscle afferent fibers through activation of peripheral 5-HT3 receptors. Pain 134(12):4150, doi:10.1016/j.pain.2007.03.034

8. Zhang ZJ, Qiang L, Kang WH, Tan QR, Gao CG, Zhang FG, Wang HH, Ma XC, Ce C, Wei W, Li G, Zhang YH, Yang XB, Zhang RG (2006) Differences in hypothyroidism between lithium-free and -treated patients with bipolar disorders. Life Sci 78(7):771776, doi:10.1016/j.lfs.2005.05.090

9. Yu WX, Zhang YH, Cai Y, Zhou XJ (2002) Chronobiologic contrast of expression of p53, p16, and cyclin D1 in hepatocarcinoma cells. Chin J Hepatol 10(4):253255

10. Christidis N, Ioannidou K, Milosevic M, Segerdahl M, Ernberg M (2008) Changes of hypertonic saline-induced masseter muscle pain characteristics,

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 11 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

by an infusion of the serotonin receptor type 3 antagonist granisetron. J Am Pain Soc 9(10):892901, doi:10.1016/j.jpain.2008.05.00211. Christidis N, Kopp S, Ernberg M (2005) The effect on mechanical pain threshold over human muscles by oral administration of granisetron and diclofenac-sodium. Pain 113(3):265270, doi:10.1016/j.pain.2004.10.016

12. Ernberg M, Lundeberg T, Kopp S (2000) Pain and allodynia/hyperalgesia induced by intramuscular injection of serotonin in patients with fibromyalgia and healthy individuals. Pain 85(12):3139

13. Ernberg M, Lundeberg T, Kopp S (2000) Effect of propranolol and granisetron on experimentally induced pain and allodynia/hyperalgesia by intramuscular injection of serotonin into the human masseter muscle. Pain 84(23):339346

14. Ernberg M, Voog U, Alstergren P, Lundeberg T, Kopp S (2000) Plasma and serum serotonin levels and their relationship to orofacial pain and anxiety in fibromyalgia. J Orofacial Pain 14(1):3746

15. Faerber L, Drechsler S, Ladenburger S, Gschaidmeier H, Fischer W (2007) The neuronal 5HT3 receptor network after 20 years of researchevolving concepts in management of pain and inflammation. Eur J Pharmacol 560(1):18, doi:10.1016/j.ejphar.2007.01.02816. Hoyer D, Clarke DE, Fozard JR, Hartig PR, Martin GR, Mylecharane EJ, Saxena PR, Humphrey PP (1994) International Union of Pharmacology classification of receptors for 5-hydroxytryptamine (Serotonin). Pharmacol Rev 46(2):157203

17. Niesler B, Walstab J, Combrink S, Moller D, Kapeller J, Rietdorf J, Bonisch H, Gothert M, Rappold G, Bruss M (2007) Characterization of the novel human serotonin receptor subunits 5-HT3C,5-HT3D, and 5-HT3E. Mol Pharmacol 72(1):817, doi:10.1124/mol.106.032144

18. Muller W, Stratz T (2004) Local treatment of tendinopathies and myofascial pain syndromes with the 5-HT3 receptor antagonist tropisetron. Scand J Rheumatol Suppl 119:4448

19. Stratz T, Farber L, Muller W (2002) Local treatment of tendinopathies: a comparison between tropisetron and depot corticosteroids combined with local anesthetics. Scand J Rheumatol 31(6):366370

20. Stratz T, Muller W (2004) Treatment of chronic low back pain with tropisetron. Scand J Rheumatol Suppl 119:7678

21. Christidis N, Nilsson A, Kopp S, Ernberg M (2007) Intramuscular injection of granisetron into the masseter muscle increases the pressure pain threshold in healthy participants and patients with localized myalgia. Clin J Pain 23(6):467472, doi:10.1097/AJP.0b013e318058abb1

22. Yang X, Zhang YH, Ding CF, Yan ZZ, Du J (2006) Extract from Morindae officinalis against oxidative injury of function to human sperm membrane. China J Chin Materia Medica 31(19):16141617

23. Cesare P, McNaughton P (1997) Peripheral pain mechanisms. Curr Opin Neurobiol 7(4):493499

24. Djouhri L, Fang X, Okuse K, Wood JN, Berry CM, Lawson SN (2003) The TTX-resistant sodium channel Nav1.8 (SNS/PN3): expression and correlation with membrane properties in rat nociceptive primary afferent neurons. J Physiol 550(Pt 3):739752, doi:10.1113/jphysiol.2003.042127

25. Jarvis MF, Honore P, Shieh CC, Chapman M, Joshi S, Zhang XF, Kort M, Carroll W, Marron B, Atkinson R, Thomas J, Liu D, Krambis M, Liu Y, McGaraughty S, Chu K, Roeloffs R, Zhong C, Mikusa JP, Hernandez G, Gauvin D, Wade C, Zhu C, Pai M, Scanio M, Shi L, Drizin I, Gregg R, Matulenko M, Hakeem A, Gross M, Johnson M, Marsh K, Wagoner PK, Sullivan JP, Faltynek CR, Krafte DS (2007) A-803467, a potent and selective Nav1.8 sodium channel blocker, attenuates neuropathic and inflammatory pain in the rat. Proc Natl Acad Sci U S A 104(20):85208525, doi:10.1073/pnas.0611364104

26. Ramachandra R, McGrew SY, Baxter JC, Kiveric E, Elmslie KS (2012) Tetrodotoxin-resistant voltage-dependent sodium channels in identified muscle afferent neurons. J Neurophysiol 108(8):22302241, doi:10.1152/jn.00219.201227. Connor M, Naves LA, McCleskey EW (2005) Contrasting phenotypes of putative proprioceptive and nociceptive trigeminal neurons innervating jaw muscle in rat. Mol Pain 1:31, doi:10.1186/1744-8069-1-31

28. Tripathi PK, Trujillo L, Cardenas CA, Cardenas CG, De Armendi AJ, Scroggs RS (2006) Analysis of the variation in use-dependent inactivation of high-threshold tetrodotoxin-resistant sodium currents recorded from rat sensory neurons. Neuroscience 143(4):923938, doi:10.1016/j.neuroscience.2006.08.052

29. Dong XW, Goregoaker S, Engler H, Zhou X, Mark L, Crona J, Terry R, Hunter J, Priestley T (2007) Small interfering RNA-mediated selective knockdown of Na(V)1.8 tetrodotoxin-resistant sodium channel reverses mechanical allodynia in neuropathic rats. Neuroscience 146(2):812821, doi:10.1016/j. neuroscience.2007.01.054

30. Zimmermann K, Leffler A, Babes A, Cendan CM, Carr RW, Kobayashi J, Nau C, Wood JN, Reeh PW (2007) Sensory neuron sodium channel Nav1.8 is

essential for pain at low temperatures. Nature 447(7146):855858, doi:10.1038/nature0588031. Gold MS, Reichling DB, Shuster MJ, Levine JD (1996) Hyperalgesic agents increase a tetrodotoxin-resistant Na + current in nociceptors. Proc Natl Acad Sci U S A 93(3):11081112

32. Zhang YH, Fehrenbacher JC, Vasko MR, Nicol GD (2006) Sphingosine-1-phosphate via activation of a G-protein-coupled receptor(s) enhances the excitability of rat sensory neurons. J Neurophysiol 96(3):10421052, doi:10.1152/jn.00120.2006

33. Zhang YH, Vasko MR, Nicol GD (2002) Ceramide, a putative second messenger for nerve growth factor, modulates the TTX-resistant Na(+) current and delayed rectifier K(+) current in rat sensory neurons. J Physiol 544(Pt 2):385402

34. Dworkin SF, LeResche L (1992) Research diagnostic criteria for temporomandibular disorders: review, criteria, examinations and specifications, critique. J Craniomandibular Disord 6(4):301355

35. Welker JA, Henshaw RM, Jelinek J, Shmookler BM, Malawer MM (2000) The percutaneous needle biopsy is safe and recommended in the diagnosis of musculoskeletal masses. Cancer 89(12):26772686

36. Liang DY, Li X, Clark JD (2011) 5-hydroxytryptamine type 3 receptor modulates opioid-induced hyperalgesia and tolerance in mice. Anesthesiology 114(5):11801189, doi:10.1097/ALN.0b013e31820efb1937. Pinto FM, Ravina CG, Fernandez-Sanchez M, Gallardo-Castro M, Cejudo-Roman A, Candenas L (2009) Molecular and functional characterization of voltage-gated sodium channels in human sperm. Reprod Biol Endocrinol 7:71, doi:10.1186/1477-7827-7-71

38. Pierce PA, Xie GX, Levine JD, Peroutka SJ (1996) 5-Hydroxytryptamine receptor subtype messenger RNAs in rat peripheral sensory and sympathetic ganglia: a polymerase chain reaction study. Neuroscience 70(2):553559

39. Renganathan M, Cummins TR, Waxman SG (2001) Contribution of Na(v)1.8 sodium channels to action potential electrogenesis in DRG neurons.

J Neurophysiol 86(2):629640

40. Blair NT, Bean BP (2002) Roles of tetrodotoxin (TTX)-sensitive Na + current, TTX-resistant Na + current, and Ca2+ current in the action potentials of nociceptive sensory neurons. J Neurosci 22(23):1027710290

41. Coward K, Plumpton C, Facer P, Birch R, Carlstedt T, Tate S, Bountra C, Anand P (2000) Immunolocalization of SNS/PN3 and NaN/SNS2 sodium channels in human pain states. Pain 85(12):4150

42. Shields SD, Ahn HS, Yang Y, Han C, Seal RP, Wood JN, Waxman SG, Dib-Hajj SD (2012) Nav1.8 expression is not restricted to nociceptors in mouse peripheral nervous system. Pain 153(10):20172030, doi:10.1016/j.pain.2012.04.022

43. Ramachandra R, McGrew SY, Baxter JC, Howard JR, Elmslie KS (2013) NaV1.8 channels are expressed in large, as well as small, diameter sensory afferent neurons. Channels 7(1):3437, doi:10.4161/chan.22445

44. Akopian AN, Souslova V, England S, Okuse K, Ogata N, Ure J, Smith A, Kerr BJ, McMahon SB, Boyce S, Hill R, Stanfa LC, Dickenson AH, Wood JN (1999) The tetrodotoxin-resistant sodium channel SNS has a specialized function in pain pathways. Nat Neurosci 2(6):541548, doi:10.1038/9195

45. Khasar SG, Gold MS, Levine JD (1998) A tetrodotoxin-resistant sodium current mediates inflammatory pain in the rat. Neurosci Lett 256(1):1720

46. Kerr BJ, Souslova V, McMahon SB, Wood JN (2001) A role for the TTX-resistant sodium channel Nav 1.8 in NGF-induced hyperalgesia, but not neuropathic pain. Neuroreport 12(14):30773080

47. England S, Bevan S, Docherty RJ (1996) PGE2 modulates the tetrodotoxin-resistant sodium current in neonatal rat dorsal root ganglion neurones via the cyclic AMP-protein kinase A cascade. J Physiol 495(Pt 2):429440

48. Alfredson H, Lorentzon R (2003) Intratendinous glutamate levels and eccentric training in chronic Achilles tendinosis: a prospective study using microdialysis technique. Knee Surg Sports Traumatol Arthrosc 11(3):196199, doi:10.1007/s00167-003-0360-0

49. Schubert TE, Weidler C, Lerch K, Hofstadter F, Straub RH (2005) Achilles tendinosis is associated with sprouting of substance P positive nerve fibres. Ann Rheum Dis 64(7):10831086. doi:10.1136/ard.2004.029876

50. Ernberg M, Lundeberg T, Kopp S (2003) Effects on muscle pain by intramuscular injection of granisetron in patients with fibromyalgia. Pain 101(3):275282

51. De Ponti F (2004) Pharmacology of serotonin: what a clinician should know. Gut 53(10):15201535, doi:10.1136/gut.2003.035568

52. Guertin PA, Steuer I (2005) Ionotropic 5-HT3 receptor agonist-induced motor responses in the hindlimbs of paraplegic mice. J Neurophysiol 94(5):33973405, doi:10.1152/jn.00587.2005

Christidis et al. The Journal of Headache and Pain 2014, 15:63 Page 12 of 12

http://www.thejournalofheadacheandpain.com/content/15/1/63

53. Haus U, Spath M, Farber L (2004) Spectrum of use and tolerability of 5-HT3 receptor antagonists. Scand J Rheumatol Suppl 119:1218

54. Dickson EJ, Heredia DJ, Smith TK (2010) Critical role of 5-HT1A, 5-HT3, and 5-HT7 receptor subtypes in the initiation, generation, and propagation of the murine colonic migrating motor complex. Am J Physiol Gastrointest Liver Physiol 299(1):G144G157, doi:10.1152/ajpgi.00496.2009

55. Romeo HE, Weihe E, Muller S, Vollrath L (1993) Protein gene product (PGP)9.5 immunoreactivity in nerve fibres and pinealocytes of guinea-pig pineal gland: interrelationship with tyrosine- hydroxylase- and neuropeptide-Y-immunoreactive nerve fibres. Cell Tissue Res 271(3):47748456. Okeson JP (2013) Management of temporomandibular disorders and occlusion, 7th edn. Elsevier Inc, St. Louis, Missouri, Mosby

57. Hayot M, Michaud A, Koechlin C, Caron MA, Leblanc P, Prefaut C, Maltais F (2005) Skeletal muscle microbiopsy: a validation study of a minimally invasive technique. Eur Respir J 25(3):431440, doi:10.1183/09031936.05.00053404

58. Tortora GJ, Grabowski SR (1996) Principles of Anatomy and Physiology, 8th edn. HarperCollins College Publishers, New York

doi:10.1186/1129-2377-15-63Cite this article as: Christidis et al.: Expression of 5-HT3 receptors and

TTX resistant sodium channels (NaV1.8) on muscle nerve fibers in pain-free humans and patients with chronic myofascial temporomandibular disorders. The Journal of Headache and Pain 2014 15:63.

Submit your manuscript to a journal and benet from:

7 Convenient online submission7 Rigorous peer review7 Immediate publication on acceptance7 Open access: articles freely available online 7 High visibility within the eld7 Retaining the copyright to your article

Submit your next manuscript at 7 springeropen.com