Bite or brain: Implication of sensorimotor regulation and neuroplasticity in oral rehabilitation procedures

Functional magnetic resonance imaging (fMRI) is widely used for investigating brain activation patterns associated with chewing and clenching movements. Whether studies consistently identify similar brain loci engaged in these movements remains unknown. We investigated the consistency with which specific brain loci were reported to be activated during teeth-occluding movements, using the activation likelihood estimation (ALE) meta-analysis. Twenty fMRI studies that used fMRI to investigate brain activation during a chewing or clenching task in healthy participants were included. Data from the selected studies were pooled, and ALE methods were used to estimate the likelihood of finding a locus associated with the movements. We found that (i) The bilateral primary motor cortex/supplementary motor area/thalamus, the right primary somatosensory cortex (S1)/secondary somatosensory cortex and the posterior cerebellum (lobule VI) have been identified as reliable loci that show consistently activation when teeth occlude. (ii) The right S1 showed a significant likelihood of activation associated with both chewing and clenching, while the left S1 showed a greater likelihood of activation in chewing than in clenching. (iii) Both younger and older participants showed a significant likelihood of activation in the cerebellum. No significant cluster was identified in the contrast analysis. The fMRI studies reliably identified the sensorimotor cortex, the thalamus and the cerebellum as brain loci associated with chewing and clenching and illustrated a differential activation pattern between chewing and clenching. These findings support the use of fMRI as a potential tool for assessing brain activation patterns related to oral sensorimotor functions in humans.

Section: Discussionsupporting

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Meta‐analysis of brain mechanisms of chewing and clenching movements

Lin

2018

“…Other studies suggest that masticatory performance in the edentulous elderly may be also associated with physical performance parameters, which are significant predictors of decreased activities of daily living . Hence, a relevant impact of ageing on masticatory function is expected due to the progressive impairment on overall physical capacity, which is frequently accompanied by a decrease in body weight and muscle mass, leading to frailty and associated morbidity in the elderly …”

Section: Discussionmentioning

confidence: 99%

Individual factors associated with masticatory performance of complete denture wearers: A cross‐sectional study

Leles

Oliveira

Araújo

et al. 2019

Aim The aim of this study was to assess whether differences in inter‐individual clinical and prosthodontic variables affect masticatory performance (MP) of edentulous subjects who received new complete dentures. Materials and methods There were 204 edentulous participants who received new maxillary and mandibular complete dentures between October 2014 and March 2018 at a university clinic. MP was measured by a mixing ability test with a two‐coloured chewing gum for 20 and 50 chewing cycles. The outcome variable was the degree of colour mixing of the chewed gum, expressed by the variation of hue (VOH) and measured by electronic colourimetric analysis. Explanatory variables included gender and age, quality of the dentures, classification of edentulous ridges and prognostic features, time since the insertion of the new dentures and patient‐reported outcomes related to complete denture treatment. Bivariate correlation tests, multiple linear regression and a linear mixed model were used for data analysis. Results Mean VOH values were 0.57 (±0.13) and 0.43 (±0.16) for 20 and 50 chewing cycles, respectively. Mixing ability was higher in females than in males for 20 (P = 0.036) and 50 (P = 0.006) chewing cycles. No effects on the patient‐reported outcome measures were observed. The time since denture delivery, gender, age and Prosthodontic Diagnostic Index (PDI) score were independently associated with masticatory performance at 20 and/or 50 chewing cycles. Overall masticatory performance tested by the linear mixed‐effect model confirmed that VOH value was negatively influenced by male gender, older age and shorter time since denture delivery. Conclusion Masticatory performance seems to be improved with the continuous use of newly inserted dentures and negatively influenced by advanced age.

“…These brainstem and higher centre neurons and indeed the behaviours to which they contribute can be regulated by modulatory influences from several brainstem and higher CNS centres, examples of which are shown in Figure . These influences involve the release of several inhibitory and excitatory chemical mediators that act upon receptor processes (eg, glutamatergic, gamma‐amino butyric acid [GABA], opioid) in non‐neural cells (eg, glia) as well as neurons in the TBSNC, STN and cranial nerve motor nuclei (eg, trigeminal motor nucleus) and adjacent interneuronal sites (for review, see refs).…”

Section: Regulation Of Oro‐facial Sensorimotor Functionsmentioning

confidence: 99%

Can you be too old for oral implants? An update on ageing and plasticity in the oro‐facial sensorimotor system

Sessle

2019

This review focuses on the capacity of the brain for plasticity and the utility and efficacy of oral implants in helping to restore oro‐facial sensorimotor functions, especially in elderly patients. The review first outlines the components of the oro‐facial sensorimotor system which encompasses both oro‐facial tissues and a number of brain regions. One such region is the sensorimotor cortex that controls the activity of the numerous oro‐facial skeletal muscles. These muscles are involved in a number of functions including reflexes and the more complex sensorimotor functions of mastication, swallowing and speech. The review outlines the use by the brain of sensory inputs from oro‐facial receptors in order to provide for exquisite sensorimotor control of the activity of the oro‐facial muscles. It highlights the role in this sensorimotor control played by periodontal mechanoreceptors and their sensory inputs to the brain, and how oral implants in concert with the plastic capacity of the brain may, at least in part, compensate for reduced sensorimotor functioning when teeth are lost. It outlines findings of ageing‐related decrements in oro‐facial sensorimotor functions and control. The changes in oro‐facial tissues and the brain that underlie these ageing‐related functional alterations are also considered, along with adaptive and compensatory processes that utilise the brain's capacity for plasticity. The review also notes the evidence that rehabilitation that incorporates adjunctive approaches such as sensorimotor training paradigms in addition to oral prostheses such as implants may enhance these processes and help maintain or facilitate recovery of sensorimotor functioning in the elderly.