- 1Dental Team, and Dental Research Group on Pain and Mental Health of Institute of Psychiatry, School of Medicine, University of São Paulo, São Paulo, Brazil
- 2Division of Neuroscience, Hospital Sirio Libanês, São Paulo, Brazil
- 3School of Medicine, LIM/23 – Institute of Psychiatry, University of São Paulo, São Paulo, Brazil
- 4Biological Sciences Platform, Sunnybrook Research Institute, Toronto, ON, Canada
- 5Clinical Dentistry Department, University of Juiz de Fora, Juiz de Fora, Brazil
- 6School of Medicine, City of São Paulo University, São Paulo, Brazil
- 7Pain Center and Division of Functional Neurosurgery, Department of Neurology, School of Medicine, University of São Paulo, São Paulo, Brazil
- 8Orofacial Pain Team, Dentistry Division, School of Medicine, Hospital das Clinicas, University of São Paulo, São Paulo, Brazil
Periodontal disease (PD) is an infectious-inflammatory oral disease that is highly prevalent among adolescence and adulthood and can lead to chronic orofacial pain and be associated with anxiety, stress and depression. This study aimed to identify anxiety-like behaviors in the ligature-induced murine preclinical model of PD in different phases of the disease (i.e., acute vs. chronic). Also, we investigated orofacial mechanical allodynia thresholds and superficial cortical plasticity along the orofacial motor cortex in both disease phases. To this aim, 25 male Wistar rats were randomly allocated in acute (14 days) or chronic (28 days) ligature-induced-PD groups and further divided into active-PD or sham-PD. Anxiety-like behavior was evaluated using the elevated plus maze, mechanical allodynia assessed using the von Frey filaments test and superficial motor cortex mapping was performed with electrical transdural stimulation. We observed increased anxiety-like behavior in active-PD animals in the acute phase, characterized by decreased number of entries into the open arm extremities [t(1,7) = 2.42, p = 0.04], and reduced time spent in the open arms [t(1,7) = 3.56, p = 0.01] and in the open arm extremities [t(1,7) = 2.75, p = 0.03]. There was also a reduction in the mechanical allodynia threshold in all active-PD animals [Acute: t(1,7) = 8.81, p < 0.001; Chronic: t(1,6) = 60.0, p < 0.001], that was positively correlated with anxiety-like behaviors in the acute group. No differences were observed in motor cortex mapping. Thus, our findings show the presence of anxiety-like behaviors in the acute phase of PD making this a suitable model to study the impact of anxiety in treatment response and treatment efficacy.
Introduction
Periodontal disease (PD) is a highly prevalent chronic, infectious-inflammatory oral disease, responsible for early tooth loss, gingival bleeding and pain (1–3). It estimated that PD affects 20–50% of the global population, including adolescents, adults and seniors (4). PD is associated with depression, anxiety and stress and can lead to impoverished quality of life (5–7). Furthermore, disorders of the periodontal ligament can induce neuronal adaptations within the central nervous system, such as changes in neuronal excitability and synaptic plasticity (8, 9), which could lead to chronic and refractory craniofacial pain (1, 10, 11).
Preclinical murine models of PD are important tools for studying the pathophysiology of the disease and providing important insights for new therapies (12–14). A widely used model of PD involves the placement of ligatures in the gingival sulcus around the molar tooth (i.e., ligature-induced periodontitis model), resulting in bacteria infiltration, accumulation of biofilm and disrupting the gingival epithelium (13, 15, 16). Moreover, animal models provide the opportunity to investigate mechanisms of brain plasticity (17, 18) and distinct aspects of acute and chronic phases of diseases (19). Although increased anxiety-like behaviors have been reported in murine models of inflammatory pain (20) and trigeminal neuropathic pain (21), no study to date has evaluated the presence of anxiety-like behaviors in distinct phases of PD (i.e., acute vs. chronic).
To address this gap, in this study, we investigated anxiety-like behaviors in the acute and chronic phase of ligature-induced murine model of PD and evaluated the presence of mechanical allodynia and superficial cortical plasticity along the orofacial motor cortex on both phases of the disease.
Materials and Methods
Subjects
Twenty-five male Wistar rats (140–180 g) obtained from the animal facility of the Medical School were used in the study. Animals were housed in pairs in regular rat cages containing wood shavings (polypropylene; 40 × 34 × 17cm), with free access to food and water in a 12 h dark/light cycle (lights on at 07:00) with controlled ambient temperature (22 ± 2°C). All experiments were performed in compliance with the guidelines for ethical use of animals in research involving pain and nociception (22) and the recommendations of the Brazilian Society of Neuroscience and Behavior, which in turn are based on the US National Institutes of Health Guide for the Care and Use of Laboratory Animals. The study was reviewed and approved by the Ethics Committee of the Medical School of the University of São Paulo (protocol #380/12). Furthermore, the experiments were reported in accordance with the Animal Research Reporting of in vivo Experiments guidelines (ARRIVE; https://arriveguidelines.org/).
Study Design
Following habituation to the animal facility, animals were allocated to groups Acute (14 days of PD) or Chronic (28 days of PD) and randomly assigned to activePD or shamPD (controls), resulting in 4 groups: (I) Acute-activePD (n = 7), (II) Acute-shamPD (n = 7), (III) Chronic-activePD (n = 6), (IV) Chronic-shamPD (n = 5). The experimental schedule was designed to have both groups at the same age during behavioral tests. Prior to receiving surgery, all animals were weighed and evaluated for a baseline measure of mechanical allodynia using von Frey filaments. On the following day, surgery was performed to induce activePD or shamPD (description follows), and animals were kept in the housing room for the number of days corresponding to the assigned group (i.e., 14 or 28 days). A second body weight measure was taken 7 (Acute group) or 14 (Chronic group) days after surgery. After the waiting period, animals were weighed and tests were performed to evaluate (I) final measure of mechanical allodynia (von Frey filaments), (II) anxiety-like behavior (elevated plus maze), and (III) the superficial cortical plasticity along the orofacial motor cortex (electrical transdural stimulation). See Figure 1A for study timeline.
Figure 1. Study timeline (A) and illustration of the rat motor cortex area (B). PD, periodontal disease; Midpoint, day 7 for Acute group and day 14 for Chronic group; Last day, Day 14 for Acute group and day 28 for Chronic group.
Surgery for Induction of Periodontal Disease
Animals were anesthetized with xylazine (50 mg/kg i.m.) and ketamine (100 mg/kg i.m.) and positioned on a surgical table designed for buccal cavity procedures. The condition of the gingiva was evaluated for exclusion of possible pre-existing diseases. After buccal and tongue retraction, a cotton ligature (4.0 Ethicon, Johnson & Johnson Company) was placed around the right mandibular first molar adjacent to the gingival margin, knotted on the mesio-buccal side and remained subgingival on the lingual side, as previously described (23, 24). On activePD animals the ligature remained in place throughout the experimental period (i.e., 14 or 28 days) and on shamPD animals the ligature was removed immediately after placement (23). The placement of a cotton ligature around the right mandibular first molar tooth induces PD by facilitating bacterial invasion of the gingival sulcus (25). The development of activePD was assessed clinically at the end of the experiments based on the description of the disease presented by Messer et al. (26).
Body Weight Evaluation
Body weight was assessed by a blinded rater using a digital scale for three times throughout the study: (I) baseline measure before the surgical procedure, (II) second measure at midpoint (7 days for Acute group and 14 days for Chronic group), (III) third measure on the last day of experiment. All measures were taken on the 1st h of the light cycle.
Evaluation of Anxiety-Like Behavior
The evaluation of anxiety behavior was performed using the elevated plus maze (EPM). This test comprises a maze elevated 50 cm above the ground, consisting of two closed arms and two open arms with a free central area that allows the animal to move through all spaces (27). Rats were placed at the junction of the four arms of the maze (the central area) with the nose facing one of the closed arms and were allowed to freely explore the apparatus for 5 min and the behavior was recorded for future analysis by a single blinded observer using X-Plot Rat 2005 1.1.0 software (FFCLRP-USP Laboratory of Prof. Silvio Morato de Carvalho, PhD). The apparatus was cleaned with a 5% ethanol solution and dried with a cloth between trials. Behavioral analysis was performed as previously described (28–30) and included the frequency of occurrence and total time spent on (I) open arms, (II) freezing (total absence of animal movement with the exception of respiration), (III) stretching (stretching the full length of the body with the forelimbs while keeping the hind limbs in place, and returning to the previous position), (IV) rearing (partial or total rising on the hind limbs), and (V) dipping (sticking the head outside the maze border and toward the floor).
Mechanical Allodynia Threshold
Using a graded series of von Frey filaments (0.07–10 g–Touch Test Sensory Evaluator, CA, USA), mechanical allodynia thresholds were assessed on the ipsilateral whisker pad of all animals (activePD and shamPD), 1 day prior and 14 (Acute group) or 28 (Chronic group) days after surgery. Animals were transferred to the testing room 2 h before testing, and then individually placed in the experimental cage for a second habituation period of 10 min. A researcher blinded to group/condition performed the test, as previously described (31, 32). Briefly, animals were gently restrained with a cotton cloth and the von Frey filaments were applied in crescent order of force, with a 10 s interval between filaments. The smallest filament that elicited a back off/escape/attack reaction and/or head withdrawal in three consecutive applications was considered to be the mechanical allodynia threshold.
Superficial Cortical Plasticity Along the Orofacial Motor Cortex
Active-PD and sham-PD animals of both Acute and Chronic groups were anesthetized with xylazine (50 mg/kg i.m.) and ketamine (100 mg/kg i.m.) and positioned on a stereotaxic apparatus (David Kopf Instruments, CA, USA). Local scalp injection of 2% lidocaine (1 ml/animal) was applied for local analgesia. A median axial incision was made in the scalp, followed by bilateral craniotomy above the motor cortex (4 × 6 mm, Figure 1B), using bregma as a reference point (33, 34). Bilateral mapping was performed via electrical transdural stimulation (1–15 volts) through a bipolar electrode with 200 μm between the tips (34, 35). The electrode was fixed to the stereotaxic bar and positioned in contact with the dura-mater. Stimuli were delivered with 500 μm between each other in all directions, covering the entire exposed area. An electrical stimulator (Grass 8,800–Grass Instruments, Quincy, MA, USA) produced the electrical stimuli that consisted of 1 s trains of 10 μs biphasic cathodal pulses delivered at 100 Hz. At each cortex point, the electrical stimuli were gradually increased up to a maximum of 15 volts and the animal's motor response was visualized in an upper side view. If no movements were seen until reaching the maximum voltage, the point was considered to be non-responsive. The same number of bilateral cortical points were evaluated in all animals. At the end of the experiment, for euthanasia, animals were deeply anesthetized with thiopental 150 mg/kg i.p. (Thiopentax, Cristalia).
Statistical Analysis
Sample size calculation was performed based on the work of Meunier et al. (32) using a formula described previously (36), considering 5% of level of significance, 80% as power of the study, effect size of 12 and standard deviation of 1.5, resulting in a minimum of 4.2 rats per group. Data are reported as mean ± standard error of the mean (SEM). Statistical analysis was performed using SPSS Statistics 17.0 (IBM, 2008, USA). Mechanical allodynia threshold was evaluated as percentage of change from baseline measure ([last measure/first measure] * 100). Animals in the activePD group that presented reduced threshold and those in the shamPD group that maintained the threshold were included in the statistical analysis. The orofacial motor cortex was evaluated as the percentage of representation along the motor cortex. One animal of each group (n = 4) died during the cortical mapping procedure and were excluded from statistical analysis. Mechanical allodynia, anxiety-like behaviors (EPM) and superficial cortex mapping were analyzed using Student's t-test with independent measures, comparing activePD and shamPD animals. Body weight was analyzed using two-way repeated measures ANOVA [normal distribution Chi-Square = 3,42944, df = 1 (adjusted) p = 0,06404] and the Pearson correlation test was used for evaluating the correlation between mechanical allodynia and anxiety-like behaviors. The level of significance was set at p < 0.05 for all tests.
Results
Clinical evaluation of the PD at endpoint showed all animals in the activePD groups (Acute and Chronic groups) presenting extensive ulceration of the gingiva with involvement of neighboring tooth, gingival inflammation, erythema, edema and accumulation of dental plaque, consisting with moderate to severe PD (Figure 2A) (26). No signs of PD were detected in shamPD animals of both Acute and Chronic groups. No differences in body weight were detected between activePD and shamPD animals [Acute: F(4,64) = 0.033, p > 0.05; Chronic: F(4,34) = 0.22, p > 0.05; Table 1]. There was a reduction in the mechanical allodynia threshold in the activePD groups compared to the shamPD groups at endpoint [Acute: t(1,7) = 8.81, p < 0.001; Chronic: t(1,6) = 60, p < 0.001; Figure 2B].
Figure 2. Illustrative case of moderate to severe active periodontal disease. (A) Reduction of mechanical allodynia threshold in Acute and Chronic groups at endpoint. (B) Increase in anxiety-like behaviors in the activePD animals compared to shamPD animals of the Acute group. (C,D) Positive correlation between mechanical allodynia thresholds and anxiety-like behaviors in the Acute group (E–H). PD, periodontal disease. *indicates p < 0.05.
The EPM test showed an increase in anxiety-like behaviors in the activePD animals in the Acute group compared to shamPD animals of the same group. Specifically, the activePD group showed a decreased number of entries into the open arm extremities (Figure 2C) and reduced time spent in the open arms (Figure 2D) and open arm extremities (Figure 2D; Table 2). Also, there was a positive correlation between the mechanical allodynia threshold and anxiety-like behaviors in the Acute group (Figures 2E–H). No differences were observed in the remaining EPM parameters analyzed for the Acute group, as well as no differences in anxiety-like behaviors in animals of the Chronic group (Table 2). There were no differences observed between activePD and shamPD animals of both groups in the motor response elicited by superficial motor cortex electrical stimulation of the orofacial area, as well on areas that elicited no response (Table 3).
Discussion
Improving the knowledge on the mechanisms of PD are fundamental to develop new therapies and improve treatment efficacy. Preclinical models can provide important insights into the pathophysiology of the disease, thus a better characterization of the behavioral phenotype of these animals is necessary. The ligature-induced model of PD used in this study can be divided into two distinct phases: acute and chronic (19). While the acute phase (≤14 days) is characterized by significant bone loss, pronounced inflammation of the affected region and elevated gene expression of pro-inflammatory cytokines, the chronic phase (>14 days) shows no further progression of bone loss and a constant state of inflammation (19). Thus, the presence of inflammatory signs (e.g., of gingival growth due to edema, erythema, and areas of ulceration) are clear signs of installed PD and the intensity of the symptoms can determine the severity of the disease (26). In our study, all animals allocated in the active-PD subgroup of both Acute and Chronic groups presented moderate to severe PD at the endpoint, showing the feasibility of this model to investigate both phases of the disease.
A growing problem among patients with PD is the presence of associated anxiety traits that can lead to treatment interruption, reduced treatment efficacy and aggravation of the severity of the disease (7, 37–39). We observed increased anxiety-like behaviors in active-PD animals of the Acute phase when comparing to sham-PD animals of the same group and a positive association between anxiety and mechanical allodynia of the affected orofacial region. Although mechanical allodynia is commonly observed in patients with different stages of periodontitis (40, 41), preclinical models of periodontitis show discordant results (42, 43). These discrepancies may be due to the technique employed to assess the mechanical allodynia threshold (e.g., sedated vs. awake animals) and the murine model used (e.g., mouse vs. rat). It is known that host susceptibility is a crucial factor for the development of periodontitis (44) resulting in great variability of clinical features between studies.
The presence of anxiety-like behaviors in models of trigeminal neuropathic pain (21) and inflammatory pain (20, 45) have been described in the literature and are thought to be related to mechanisms of neuroinflammation such as glial cell activation, increase in pro-inflammatory cytokines and infiltration of leukocytes (46). Albeit our study did not aim to evaluate these markers of neuroinflammation, it is plausible to assume these same factors could be influencing anxiety-like behaviors in the ligature-induced PD model as well. To investigate possible superficial cortical plasticity that could explain the behavioral differences observed in this study, we applied electrical transdural stimulation on specific areas of the motor cortex and observed the motor response generated (35). This technique allows for the functional mapping of the surface of the neocortex by evoking motor responses on specific body segments according to the coordinates used (35). Although we did not find significant results in our study, it is possible to assume that the use of a more refined technique for the detection of muscle activity (e.g., electromyography) while mapping the surface of the orofacial motor cortex could result in distinct outcomes.
Altogether, our results show that the ligature-induced PD in the acute phase is a suitable model for the study of anxiety-like behaviors in periodontitis, thus allowing for the investigation of the possible impacts of anxiety on the individual response to treatment and general treatment efficacy.
Data Availability Statement
The data generated and analyzed during the current study are available from the corresponding author upon reasonable request.
Ethics Statement
This study has the approval of the Ethics Committee of the Medical School of the University of São Paulo (protocol number: 380/12).
Author Contributions
BV, RM, and FG performed experiments, analyzed the data, and wrote the draft manuscript. GF, GB, RA, and GA performed experiments and analyzed the data. RA, SS, MT, EF, and JS designed the study, analyzed the data, and wrote the draft manuscript. All authors contributed to manuscript revision and approved the final version.
Funding
This research was supported by FAPESP grants to RM (#11/08575-7) and FG (#13/20602-5).
Conflict of Interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Acknowledgments
The authors are grateful to Professor José Pinhata Otoch, Mr. Elias Aparecido, and Mrs. Junko Takano Osaka from the Medical Investigation Laboratory (LIM 26), Department of Surgery Technique, School of Medicine, University of São Paulo, Brazil.
References
1. Fabri GMC, Siqueira SRDT, Simione C, Nasri C, Teixeira MJ, Siqueira JTT. Refractory craniofacial pain: is there a role of periodontal disease as a comorbidity? Arq Neuropsiquiatr. (2009) 67:474–9. doi: 10.1590/S0004-282X2009000300018
2. Campos Fabri GM, Savioli C, Tesseroli Siqueira JT. Periodontal treatment and quality of life of chronic facial pain patients. Int J Odontostomat. (2014) 8:247–52. doi: 10.4067/S0718-381X2014000200017
3. Kongstad J, Enevold C, Christensen LB, Fiehn N-E, Holmstrup P. Impact of periodontitis case criteria: a cross-sectional study of lifestyle. J Periodontol. (2017) 88:602–9. doi: 10.1902/jop.2017.160426
4. Nazir MA. Prevalence of periodontal disease, its association with systemic diseases and prevention. Int J Health Sci. (2017) 11:72–80.
5. Laforgia A, Corsalini M, Stefanachi G, Pettini F, Di Venere D. Assessment of psychopatologic traits in a group of patients with adult chronic periodontitis: study on 108 cases and analysis of compliance during and after periodontal treatment. Int J Med Sci. (2015) 12:832–9. doi: 10.7150/ijms.12317
6. Levin L, Zini A, Levine J, Weiss M, Lev RA, Hai A, et al. Dental anxiety and oral health-related quality of life in aggressive periodontitis patients. Clin Oral Investig. (2018) 22:1411–22. doi: 10.1007/s00784-017-2234-8
7. Kesim S, Unalan D, Esen C, Ozturk A. The relationship between periodontal disease severity and state-trait anxiety level. J Pak Med Assoc. (2012) 62:1304–8.
8. Ebadian AR, Kadkhodazadeh M, Soltanian N, Amid R. Hyperpolarization-activated cyclic nucleotide-gated 2 (HCN2) polymorphism is associated with chronic inflammatory periodontitis. A cross-sectional study. J Basic Clin Physiol Pharmacol. (2013) 24:241–4. doi: 10.1515/jbcpp-2013-0028
9. Sood M, Lee J-C, Avivi-Arber L, Bhatt P, Sessle BJ. Neuroplastic changes in the sensorimotor cortex associated with orthodontic tooth movement in rats. J Comp Neurol. (2015) 523:1548–68. doi: 10.1002/cne.23753
10. Siqueira de JTT, Lin HC, Nasri C, Siqueira de SRDT, Teixeira MJ, Heir G, et al. Clinical study of patients with persistent orofacial pain. Arq Neuropsiquiatr. (2004) 62:988–96. doi: 10.1590/S0004-282X2004000600011
11. de Siqueira SRDT, Vilela TT, Florindo AA. Prevalence of headache and orofacial pain in adults and elders in a Brazilian community: an epidemiological study. Gerodontology. (2015) 32:123–31. doi: 10.1111/ger.12063
12. Struillou X, Boutigny H, Soueidan A, Layrolle P. Experimental animal models in periodontology: a review. Open Dent J. (2010) 4:37–47. doi: 10.2174/1874210601004010037
13. Oz HS, Puleo DA. Animal models for periodontal disease. J Biomed Biotechnol. (2011) 2011:754857. doi: 10.1155/2011/754857
14. Hajishengallis G, Lamont RJ, Graves DT. The enduring importance of animal models in understanding periodontal disease. Virulence. (2015) 6:229–35. doi: 10.4161/21505594.2014.990806
15. Abe T, Hajishengallis G. Optimization of the ligature-induced periodontitis model in mice. J Immunol Methods. (2013) 394:49–54. doi: 10.1016/j.jim.2013.05.002
16. Donos N, Park J-C, Vajgel A, de Carvalho Farias B, Dereka X. Description of the periodontal pocket in preclinical models: limitations and considerations. Periodontol. (2018) 76:16–34. doi: 10.1111/prd.12155
17. Thibault K, Rivière S, Lenkei Z, Férézou I, Pezet S. Orofacial neuropathic pain leads to a hyporesponsive barrel cortex with enhanced structural synaptic plasticity. PLoS ONE. (2016) 11:e0160786. doi: 10.1371/journal.pone.0160786
18. Kaneko M, Fujita S, Shimizu N, Motoyoshi M, Kobayashi M. Experimental tooth movement temporally changes neural excitation and topographical map in rat somatosensory cortex. Brain Res. (2018) 1698:62–9. doi: 10.1016/j.brainres.2018.06.022
19. de Molon RS, Park CH, Jin Q, Sugai J, Cirelli JA. Characterization of ligature-induced experimental periodontitis. Microsc Res Tech. (2018) 81:1412–21. doi: 10.1002/jemt.23101
20. Parent AJ, Beaudet N, Beaudry H, Bergeron J, Bérubé P, Drolet G, et al. Increased anxiety-like behaviors in rats experiencing chronic inflammatory pain. Behav Brain Res. (2012) 229:160–7. doi: 10.1016/j.bbr.2012.01.001
21. Gambeta E, Batista MA, Maschio GP, de Turnes JM, Araya EI, Chichorro JG. Anxiety- but not depressive-like behaviors are related to facial hyperalgesia in a model of trigeminal neuropathic pain in rats. Physiol Behav. (2018) 191:131–7. doi: 10.1016/j.physbeh.2018.04.025
22. Zimmermann M. Ethical guidelines for investigations of experimental pain in conscious animals. Pain. (1983) 16:109–10. doi: 10.1016/0304-3959(83)90201-4
23. Brito LCW, DalBó S, Striechen TM, Farias JM, Olchanheski LR Jr, Mendes RT, et al. Experimental periodontitis promotes transient vascular inflammation and endothelial dysfunction. Arch Oral Biol. (2013) 58:1187–98. doi: 10.1016/j.archoralbio.2013.03.009
24. de Molon RS, de Avila ED, Boas Nogueira AV, Chaves de Souza JA, Avila-Campos MJ, de Andrade CR, et al. Evaluation of the host response in various models of induced periodontal disease in mice. J Periodontol. (2014) 85:465–77. doi: 10.1902/jop.2013.130225
25. Genco CA, Van Dyke T, Amar S. Animal models for Porphyromonas gingivalis-mediated periodontal disease. Trends Microbiol. (1998) 6:444–9. doi: 10.1016/S0966-842X(98)01363-8
26. Messer JG, Jiron JM, Chen H-Y, Castillo EJ, Mendieta Calle JL, Reinhard MK, et al. Prevalence of food impaction-induced periodontitis in conventionally housed marsh rice rats (Oryzomys palustris). Comp Med. (2017) 67:43–50.
27. Pellow S, Chopin P, File SE, Briley M. Validation of open: closed arm entries in an elevated plus-maze as a measure of anxiety in the rat. J Neurosci Methods. (1985) 14:149–67. doi: 10.1016/0165-0270(85)90031-7
28. Anseloni VZ, Brandão ML. Ethopharmacological analysis of behaviour of rats using variations of the elevated plus-maze. Behav Pharmacol. (1997) 8:533–40. doi: 10.1097/00008877-199711000-00011
29. Garcia AMB, Martinez R, Brandão ML, Morato S. Effects of apomorphine on rat behavior in the elevated plus-maze. Physiol Behav. (2005) 85:440–7. doi: 10.1016/j.physbeh.2005.04.027
30. Filgueiras GB, Carvalho-Netto EF, Estanislau C. Aversion in the elevated plus-maze: role of visual and tactile cues. Behav Processes. (2014) 107:106–11. doi: 10.1016/j.beproc.2014.08.005
31. Ren K, Dubner R. Inflammatory models of pain and hyperalgesia. ILAR J. (1999) 40:111–8. doi: 10.1093/ilar.40.3.111
32. Meunier A, Latrémolière A, Mauborgne A, Bourgoin S, Kayser V, Cesselin F, et al. Attenuation of pain-related behavior in a rat model of trigeminal neuropathic pain by viral-driven enkephalin overproduction in trigeminal ganglion neurons. Mol Ther. (2005) 11:608–16. doi: 10.1016/j.ymthe.2004.12.011
33. Krieg WJS. Connections of the cerebral cortex; the albino rat; topography of the cortical areas. J Comp Neurol. (1946) 84:221–75. doi: 10.1002/cne.900840205
34. Paxinos G, Watson C. The Rat Brain in Stereotaxic Coordinates: Hard Cover Edition. San Diego: Elsevier Academic Press (2006).
35. Fonoff ET, Pereira JF Jr, Camargo LV, Dale CS, Pagano RL, Ballester G, et al. Functional mapping of the motor cortex of the rat using transdural electrical stimulation. Behav Brain Res. (2009) 202:138–41. doi: 10.1016/j.bbr.2009.03.018
36. Charan J, Kantharia ND. How to calculate sample size in animal studies? J Pharmacol Pharmacother. (2013) 4:303–6. doi: 10.4103/0976-500X.119726
37. Khambaty T, Stewart JC. Associations of depressive and anxiety disorders with periodontal disease prevalence in young adults: analysis of 1999-2004 National Health and Nutrition Examination Survey (NHANES) data. Ann Behav Med. (2013) 45:393–7. doi: 10.1007/s12160-013-9471-0
38. Delgado-Angulo EK, Sabbah W, Suominen AL, Vehkalahti MM, Knuuttila M, Partonen T, et al. The association of depression and anxiety with dental caries and periodontal disease among Finnish adults. Community Dent Oral Epidemiol. (2015) 43:540–9. doi: 10.1111/cdoe.12179
39. Kolte PA, A Kolte R, N Lathiya V. Association between anxiety, obesity and periodontal disease in smokers and non-smokers: a cross-sectional study. J Dent Res Dent Clin Dent Prospects. (2016) 10:234–40. doi: 10.15171/joddd.2016.037
40. Alelyani AA, Azar PS, Khan AA, Chrepa V, Diogenes A. Quantitative assessment of mechanical allodynia and central sensitization in endodontic patients. J Endod. (2020) 46:1841–8. doi: 10.1016/j.joen.2020.09.006
41. Khan AA, Owatz CB, Schindler WG, Schwartz SA, Keiser K, Hargreaves KM. Measurement of mechanical allodynia and local anesthetic efficacy in patients with irreversible pulpitis and acute periradicular periodontitis. J Endod. (2007) 33:796–9. doi: 10.1016/j.joen.2007.01.021
42. Mohaved SB, Shilpa G, Li Q, Austah O, Bendele M, Brock R, et al. Apical periodontitis-induced mechanical allodynia: a mouse model to study infection-induced chronic pain conditions. Mol Pain. (2020) 16:1744806919900725. doi: 10.1177/1744806919900725
43. Nagashima H, Shinoda M, Honda K, Kamio N, Watanabe M, Suzuki T, et al. CXCR4 signaling in macrophages contributes to periodontal mechanical hypersensitivity inPorphyromonas gingivalis-induced periodontitis in mice. Molecular Pain. (2017) 13:174480691668926. doi: 10.1177/1744806916689269
44. Silva N, Abusleme L, Bravo D, Dutzan N, Garcia-Sesnich J, Vernal R, et al. Host response mechanisms in periodontal diseases. J Appl Oral Sci. (2015) 23:329–55. doi: 10.1590/1678-775720140259
45. Wu Y, Yao X, Jiang Y, He X, Shao X, Du J, et al. Pain aversion and anxiety-like behavior occur at different times during the course of chronic inflammatory pain in rats. J Pain Res. (2017) 10:2585–93. doi: 10.2147/JPR.S139679
Keywords: nociception and pain, periodontal disease, anxiety, animal model, neuroplasticity
Citation: Varotto BLR, Martinez RCR, Gouveia FV, Antunes GF, Fabri GMdC, Ballester G, Antequera R, de Siqueira SRDT, Fonoff ET, Teixeira MJ and de Siqueira JTT (2020) Increased Anxiety-Like Behavior in the Acute Phase of a Preclinical Model of Periodontal Disease. Front. Neurol. 11:598851. doi: 10.3389/fneur.2020.598851
Received: 27 August 2020; Accepted: 30 November 2020;
Published: 22 December 2020.
Edited by:
Massimiliano Valeriani, Bambino Gesù Children Hospital (IRCCS), ItalyReviewed by:
Wolnei Caumo, Clinical Hospital of Porto Alegre (HCPA), BrazilPhillip R. Kramer, Texas A&M University, United States
Copyright © 2020 Varotto, Martinez, Gouveia, Antunes, Fabri, Ballester, Antequera, de Siqueira, Fonoff, Teixeira and de Siqueira. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Raquel Chacon Ruiz Martinez, quelmartinez@yahoo.com.br
†These authors have contributed equally to this work
‡These authors have jointly supervised this work