Difference between revisions of "4° Clinical case: Temporomandibular disorders"

In the 'Introduction' chapter, we presented a demonstrative clinical case that challenged the concept of 'Malocclusion' in the sense that any class or occlusal morphology should always be related to trigeminal neuromotor responses to confirm the presence of a masticatory pathological disorder. In that case, the subject was found to have a perfect symmetry in latency, amplitude and integral areas of the trigeminal Central Nervous System (tCNS) and therefore hardly classifiable as 'malocclusion'. It should be borne in mind, however, that the subject in question with an obvious occlusal abnormality had absolutely no chewing disorder but what happens in a similar subject who reports orofacial pain and joint disorders. We will see in this chapter how such a patient should be considered and we will conclude with an exposition of the steps used for prosthetic rehabilitation performed with a trigeminal electrophysiological method called 'NGF model' which will be transformed, in the course of the Masticationpedia edition, into a diagnostic model called 'Index ${\displaystyle \Psi }$'.

Article by  Gianni Frisardi

 

Introduction

An article by Ahmad and Schiffman^[1] revealed interesting elements that call for a more in-depth analysis of the TMD phenomenon. The authors reported, in fact, that about 5-12% of the US population is affected by TMD and the annual cost of TMD management, excluding imaging costs, is about $4 billion. Interview Survey (NHIS) that included a total of 189,977 people, 4.6% (n = 8964) had temporomandibular joint and muscle disorders (TMJD).

As we have already mentioned several times in the previous chapters, one of the critical elements in the differential diagnosis between orofacial pain and TMD is the datum of the incidence of the disease, which necessarily pollutes the result of the predictive value of Bayes' theorem. In this case, from the authors' considerations^[1] we are at 4.6 per cent.

We know by now that 'TMD' is the second most common chronic musculoskeletal condition after chronic low back pain^[2] and although Ahmad and Schiffman^[1] have exhaustively reported on the importance of imaging to make correct intra-articular diagnoses of TMJ, the doubt arises of the overlapping of symptomatic-clinical states as we have seen in the clinical cases reported in the previous chapters of Masticationpedia.

This interference does not depend on the physician's ability but on the deterministic forma mentis that leaves no room for the phenomenon of overlapping pathologies simulating the same TMD symptomatology. A quick roundup of clinical cases reported in the chapters of Masticationpedia can remind us better of the complexity and truthfulness of this statement. (Figure 1)

Rightly says Magda Krasińska-Mazur et al.^[3] that the correct diagnosis of temporomandibular disorders is based on anamnesis and a thorough physical examination, as well as the results of additional tests.....but which ones?

So far we have discussed many aspects that in some way delay the differential diagnosis in patients who report overlapping symptomatology and various clinical manifestations, a differential diagnosis that if, on the other hand, performed correctly and quickly could save the subject's life as happened to our 'Bruxer' and unfortunately not to our 'Balancer'. The doctor's forma mentis in these cases is fundamental and the decisive element remains that of stepping out of the 'specialist context' in order to take an indeterministic and probabilistic view of medicine at the same time. This is no different with regard to patients actually suffering from TMDs because there is no real neuro-gnathological discipline, the diagnosis as well as the therapy of these subjects remains the standard one, namely gnathological. The discipline of gnathology, although very valid, is also limited because it restricts the field of the 'observable' to the occlusal parameter, disregarding everything else that is part of the masticatory neuromotor network and beyond.^[4] We will present this clinical case of a patient with DTMs to give a significant clinical diagnostic/therapeutic change in the field of 'Functional Neuro Gnathology' calling it, precisely, the NGF method.

Anamnesis

Figura 2: Situazione orla del paziente affetto da DTMs in cui si evince il cross bite anteriore

As usual, we call our patient with a fancy name and precisely 'Clicker' because the patient had been suffering from temporomandibular joint (TMJ) clicks for years. Clicker presented to our neuropathology department complaining of severe orofacial pain and reporting a chronic right TMJ joint removal. She arrived after having already been diagnosed as DTMs always following the RDC protocol and treated with a biteplane to manage the nocturnal teeth grinding only. She, a 40-year-old patient who reported orofacial pain with joint noises such as clicks and crashes on both sides of the face and difficulty in chewing.

A first clinical occlusal examination shows a functional occlusal class III with sliding in protrusion in reaching the maximum intercuspidation. On palpation, the masseters, temporals, and external pterygoids on both sides were tender. No balance and gait disturbances, no vertigo, no tinnitus but as our routine we immediately performed trigeminal electrophysiological tests in order to avoid any structural involvement of the trigeminal Central Nevous System (_tNCS). As already explained in the chapter concerning the 'Balancer' patient with Meningioma in which the interference EMG examination performed by the dental colleagues did not give indications of organic pathology of the tNCS in our Diagnostic Center we only perform Evoked Potentials and the battery of trigmeinal reflexes. In this chapter, taking into account the clinical situation, we have bypassed the purely dental context as, after an initial objective examination, the malocclusive disorder is striking but not certain (figure 2).

Figura 3: Esami elettrofiologici di tipo Neuro Gnatologico Funzionale

Trigeminal electrophysiology

As has now been documented in the previous chapters of Masticationpedia, the heart of the scientific philosophy of Masticationpedia is substantially the normalization of masticatory functions to the Central Nervous System and trigeminal peripheral _tCNS and not to dental occlusion. This is able to couple the occlusal abnormality to the 'state' conditions of the tCNS as well documented in the first chapter 'Introduction' where we showed a perfect trigeminal electrophysiological symmetry in the subject with severe dental malocclusion and a frankly asymmetric neuromotor condition in a subject with perfect occlusion after being treated with orthognathic surgery. The electrophysiological tests in subjects with TMDs are limited to the bilateral Motor Evoked Potentials of the trigeminal roots which we have precisely put over the years called bRoot-MEPs,^[5] from the jaw jerk^[6] performed while keeping the mandible in the rest position (Jaw jerk in rest position) and the jaw jerk keeping the jaw closed with moderate muscle activity (jaw jerk in occlusal position).

_bRoot-MEPs

In figure 3 we can see the responses of the motor evoked potentials of the two trigeminal roots, the jaw jerk in the rest position and in the position of maximum intercuspidation. In particular, the Nervous system responds to Transcranial Electrical Stimulation of the trigeminal roots with two evoked potentials that are perfectly symmetrical both in latency and in amplitude and specifically the latencies are positioned at an onset of ${\displaystyle 1R=2,01}$ms and ${\displaystyle 1L=1,99}$ms while the peak-to-peak amplitudes ${\displaystyle 2R-3R=5}$ mV and ${\displaystyle 2L-3L=5,2}$ mV. This result is fundamental for the differential diagnosis between organic and functional pathologies, in fact, it demonstrates that the system is organically symmetrical and synchronous and this determines the term that we will see recur in a decisive way in the continuation of the Masticationpedia chapters called 'Organic Symmetry'. Bear in mind right now that the 'Organic Symmetry' parameter will be considered an element of 'Normalization' of the trigeminal reflex responses as its latency and amplitude symmetry indicates a perfect 'state' of integrity of the _tCNS and that at the same time one should expect an equally 'state' of functional symmetry due to trigeminal reflex responses. Let's see, therefore, the trigeminal functional 'state' of the _tCNS by analyzing the jaw jerk.

Jaw jerk in rest position

The stretch reflex test called jaw jerk was performed keeping the mandible in rest position to distinguish the input component to the tCNS excluding the input of the periodonatal receptors. The results were not encouraging due to the relative asymmetry of latency (${\displaystyle 1R=8,5}$ms and ${\displaystyle 1L=7,5}$ ms) and peak-to-peak amplitude (${\displaystyle 2R-3R=0,3}$mV; ${\displaystyle 2L-3L=0,6}$mV). In particular, the latency delay could be explained by a facilitation on gamma motor neurons, in contrast with the study by Kitagawa et al.^[7] in which it is asserted that the facilitation on the ipsilateral side could be produced by an enhancement of the gamma drive induced by a prolonged nociceptive stimulation. In our case the most significant datum is the difference of ${\displaystyle \simeq 50\%}$ with reduction on the right affected side. We have noticed in our studies that in the rest position the jaw jerk also shows a dependence not only on the acceleration of the trigger stroke but also on the spatial position of the jaw as it is not conditioned by the occlusal position.^[6]

Jaw jerk in rest position

The jaw jerk, keeping the mandible in a position of centric occlusion, performed to verify the contribution of the periodontal receptors together with the muscle and tendon proprioceptors, was obviously facilitated by the dental contact but the asymmetry in amplitude (${\displaystyle 2R-3R=0,1}$mV; ${\displaystyle 2L-3L=1}$ mV) increased. This result agrees with what was stated in a study by Yoshino T et al.^[8] in which the mandibular position was deviated by 0.5, 1.0, 1.5, 2.0 and 3.0 mm to the right and left from a reference position corresponding to the rest position. Jaw jerk amplitude on the mediotrusive side increased primarily in proportion to mandibular deviation. The study concludes by suggesting that jaw jerk may aid the clinical examination of minor mandibular deviations. The conclusion of this 1st trigeminal electrophysiological step was to ascertain the organic integrity of the _tCNS through the symmetry and synchronics of the _bRoot-MEPs,^[5] and consider it as an 'Organic Symmetry',^[9] i.e. normalizer of the masticatory neurophysiological process while the asymmetries of the jaw jerk a functional disorder due to an unbalanced peripheral input or an inhibitory process on the trigeminal motoneurons of the nociceptive type. In essence, the conclusion of a mandibular spatial disorder would seem more indicative, which we will ascertain later when the Neuro Evoked Centric Relationship is performed to verify the physiological spatial position.

Silent period of the masticator muscles

Figura 4: Periodo silente dei muscoli masticatori e rappresentazione delle aree di interesse segnalate con frecce.

Figure 4 shows the neuromuscular responses of the silent period to chin percussion through a triggered neurological hammer when the patient was asked to clench her teeth maximally. If from a neurological point of view it is not possible to highlight elements referable to organic alterations of the _tCNS, some electrophysiological characteristics, however, are to be referred to a functional disorder of the system. In the upper trace, a decrease in the motor neuron reactivation phase can be seen immediately following the silent period. The possible neurophysiological mechanism capable of determining a similar decrease in facilitatory activities on the mandibular silent period can be ascribed to a change in the spindle motor drive induced by the input of muscle proprioceptors and nociceptors. The neuronal network of this process would take place through a loop formed by: muscle nociceptive afferents, the subnucleus caudalis of the V, inhibitory interneurons on static motor neurons and, as a last link, the modulation of the sensitivity of the neuromuscular spindles..^{[10] [11][12][13][14][15]} Also in this context the inhibitory component most likely prevails over the excitatory one and this could be ascribed to a malocclusion as we will see later. In particular, it can be noted the overlapping of the jaw jerk behavior, previously tested, in a path rectification condition. The arrow indicates the jaw jerk on all traces and the decrease in amplitude can be observed for the right masseter while it is relatively symmetrical on the temporal muscles.

Mandibular spatial analysis

On this subject unfortunately there are innumerable conceptual conflicts redundant regularly coming back into vogue after a period of years such as the gothic arch tracing method to determine the centric relationship of full dentures, as suggested by Zhou TF et al.^[16] From what has been exposed in all the chapters previously published on Masticationpedia, it is clear that the approximation of manual methods or vague interpretations derived from a logic of verbal language cannot be represented in the scientific philosophy of Masticationpedia which tends to focus on a mesoscopic model more than macroscopically descriptive and formal through statistical mathematical models as we will see below. Therefore we do not share the opinion of Zhou TF et al but absolutely in line with the concepts expressed by Silva Ulloa S. et al.^[17] in which it is concluded that the sensorimotor cortex is affected by changes in occlusion and it is hypothesized that occlusion may play an important role in the development of diseases, from anxiety and stress to Alzheimer's disease and senile dementia. We also share the heartfelt suggestion of Silva Ulloa S. et al. in which she urges dentists to consider that alterations in the occlusal pattern during chewing can lead to changes in the activation of several brain regions related to memory, learning, anticipatory pain and anxiety.

Therefore, it is essential to operate in synergy with the trigeminal neuromotor content in order to have an 'Observable' more indicative of the masticatory reality and in this case of the real spatial position that the jaw wants to reach beyond the dental interference. To achieve this target we have developed a method of simultaneous Transcranial Electrical Stimulation of the trigeminal roots which evokes a direct response of all the masticatory muscles which we call _bRoot-MEPs as previously mentioned which has an indication of the 'state' integrity of the _tCNS and at the same time it determines an elevation of the mandible from the rest position to the Occlusal Centric. This Centric has been named by us Functional Neuro Evoked Centric. (Figure 5)

As we can see, starting directly from a neurological context, using advanced trigeminal electrophysiological technologies, we have avoided the presence of destructuring of the _tCNS and contextually highlighted a spatial-type occlusal disorder. The mandible with this method which generates a synchronous action potential of all the muscles innervated by the trigeminal roots, apart from conditions of marked destructuring of the ATM, generates a perfectly physiological closure which in this case is interrupted by the presence of a dental interference of the element 21 which comforts us in continuing the functional neurognathological treatment.

Functional Neuro Gnathological rehabilitation

Regarding the treatment of patients with TMDs there are still many strategic-conceptual conflicts such as, for example, the use of TENS^[18] which the RDC protocol has considered clinically invalid as much as from a neurophysiological point of view TENS is not an appropriate method for not being able to evoke a response from all masticatory muscles but only the superficial ones. In this limitation lies the spatial error of the mandibular position which would be in a more anterior position due exclusively to the motor response of the masseter muscle (a topic which will be dealt with in the section 'Crisis of the Paradigm').

For this reason we bypass the manufacture of a bite plane to arrive directly at the definitive neurognathological prosthetic rehabilitation. In this specific case it was a Functional Neuro Evoked Centric rehabilitation of the anterior incisors and the four lower molars, two per side. The realization, however, followed some particularly obligatory pre-ordered steps which represent the best way to achieve real neuro-occlusal stability, as we will see in detail below. (figure 6)

In figure 6a we can see the structures of the crowns in the mouth on which the ceramic will be stratified and which will be covered with Aluvax wax to determine the Functional Neuro Evoked Centric. The decision to incorporate the four molars in the rehabilitation was made because these elements are crucial for occlusal stability but also for mediotrusion as we will see below. The exact mandibular position requires a third anterior point and for this reason, also considering the wear of the incisions and the importance of a normocclusion of the anterior sector, the involvement of the incisors was decisive for Centering the mandible in the optimal position (figure 6b) . Obviously, everything is brought back into articulate with mold waxes on Empress crowns. (figure 6c)

Functional Neuro Gnatologic Detail

For Neuro Gnatologic Functional detail, rehabilitation model called 'NGF Index' from which a whole scientific process will be initiated which will lead to a diagnostic paradigmatic model called 'NGF Index' in the 'Extraordinary Science' section, means an occlusal adjustment normalized to trigeminal neuromotor symmetry . To achieve this goal, gnathological replicates (articulated) and above all the ability to read the evoked and reflex responses of the tCNS in different occlusal situations are fundamental. For this reason, only the active centrics of the Empress crowns were stratified on the four lower molars. (figure 7)

In figura 7a,b e c sono state stratificate soltanto le centriche attive dei molari perchè nonostante la registrazione Centrica Neuro Evocate Funzionale sia di assoluta precisione, il trasferimento meccanico dalla bocca al laboratorio ( articolatore) potrebbe incorporare minimi variazioni spaziali. Per questo motivo si è deciso di fermare la chiusura neuro evocata della mandibola leggermente rialzata per poter aver la disponibilità del materiale ceramico da rimodellare seguendo le risposte elettrofisiologiche trigeminali. In sostanza le cuspidi venivano abrase settorialmente e singolarmente per poi comparare con le risposte elettrofisiologiche trigeminali fino alla perfetta simmetria e sincornicità del _tCNS. Una volta raggiunto il risultato di simmetria e sincronici la posizione raggiunta diventerà l'asta incisale a zero per concludere la stratificazione.

In figura 8a ed 8b si possono notare le straordinarie differenze nella risposta neuromotoria trigeminale dovute, essendo di tipo funzionale, ad un cambiamento spaziale mandibolare ed un accurato equilibratura neurognatologica occlusale. Si può assistere, infatti, ad una simmetrizzazione del jaw jerk sul massetere destro, ad una diminuzione della durata del periodo silente meccanico e soprattutto una ottimale riattivazione motoneurale dopo il periodo silente (effetto rebound) che sta a significare sicurezza nella riattivazione totale ed immediata della scarica motoneurale. Una volta documentato con dati inconfutabili questa re-simmetrizzazione neuromotoria trigeminale si può passare alla finalizzazione del caso clinico.

Riabilitazione protesica NGF

La finalizzazione del caso clinico diagnosticato definitivamente DTMs ha determinato un ripristino della funzione masticatoria, scomparsa dei sintomi nonché un miglioramento estetico. Le varie fasi della riabilitazioni si possono seguire nella galleria delle immagini della figura 9. In particolare la posizione Centrica Neuro Evocata Funzionale non solo è centrata essendosi spostata leggermente a destra ma anche retrusa. E' interessante fare una comparazione conn la figura 5a per rendersi conto delle differenze spaziali. L'elemento 22, infatti, non è più in crossbite ma in una posizione di testa a testa mentre il 23 ha un contatto centrica molto più incisale rispetto alla situazione clinica precedente, così pure da notare lo spazio occlusale nell'area mediale del 24 che si è venuto a generare con la attuale posizione spaziale mandibolare determinata con la Centrica Neuro Evocata Funzionale. Questo nuovo assetto occlusale è stato possibile solo perchè la posizione centrica stabile e principalmente congelata nel settore dei molari. I molari attraverso l'equilibrio neuromotorio esposto precedentemente sulla cuspide centrica stabilizza l'occlusione e genera un bilanciamento bilaterale nei movimenti mandibolari come sarà a breve descritto.

In figura 9c e 9d, possiamo notare non solo i contatti centrici ben bilanciati ma soprattutto le escursioni mediotrusive. Su questo argomento bisognerebbe spendere qualche parola in più. Benedikt Sagl et al.^[19] affermano, nel loro studio in cui si è analizzato il contributo dell'inclinazione dei denti, dell'escursione mediottrusiva e laterotrusiva e gli stress von Mises sul disco articolare, che il bruxing mediotrusivo genera carichi più elevati rispetto alle simulazioni laterotrusive. In questo senso non si capisce bene se i contatti mediotrusivi siano un elemento protettivo oppure peggiorativo nella generazione di disturbi dell'articolazione temporomandibolare. Tanto è vero che un articolo di Walton TR e Layton DM^[20] la confusione aumenta in quanto affermano dapprima che la presenza di interferenze MT nelle popolazioni di pazienti, è ampia e varia dallo 0% al 77% per poi concludere che le interferenze MT dovrebbero essere evitate in qualsiasi schema terapeutico occlusale per ridurre al minimo le complicanze pulpari, parodontali, strutturali e meccaniche o l'esacerbazione dei disturbi temporomandibolari (TMD). La confusione aumenta quando conclude che le interferenze MT molari naturali dovrebbero essere eliminate solo se sono presenti segni e sintomi di TMD. La domanda che sorge è la seguente

Bisognerebbe fare un pò d'ordine sull'argomento iniziando con lo specificare che cosa si intende per interferenza.

Uno studio di Leitão AWA et al.^[21] è straordinariamente significativo avendo simulato oggettivamente l'interferenza sull'animale ed analizzato istologicamente i cambiamenti a livello del ganglio trigmeinale contestualmente al comportamento dell'animale quando trattati con o senza inibitore selettivo della cicloossigenasi 2 (COX-2). Gli autori, inoltre, hanno trattato gli animali con infusione giornaliera di con 0,1 ml/kg di soluzione fisiologica (DOI+SAL) e , 16 o 32 mg/kg di celecoxib (DOI+cel -8, -16, -32). Hanno notato che gli animali sottoposti ad interferenze ed alla stimolazione nocicettiva del massetere lo DOI + SAL ha mostrato un aumento della nocicezione isplaterale (P <0,001) e controlaterale (P <0,001), un aumento del numero di morsi (P = 0,010), graffi (P <0,001) e punteggi delle smorfie (P = 0,032) mentre nel gruppo di DOI+cel-32, questi parametri sono stati ridotti.

Questo studio interessante mostra la correlazione tra interferenza, diminuzione della soglia per il doloro e contestualmente il ripristino con infusione di celecoxib e dunque correlazione neuro-occlusale.

Si-Yi Mo et al.^[22] rafforza la correlazione neuro-occlusale di cui sopra dimostrando che il percorso discendente dai neuroni serotoninergici (5-HT) al midollo ventromediale rostrale (RVM) ai recettori 5-HT3 nel nucleo del trigemino spinale (Sp5), gioca un ruolo importante nel facilitare il mantenimento dell'iperalgesia orofacciale dopo la rimozione ritardata dell'interferenza occlusale sperimentale (REOI).

Fin qui abbiamo una visione più vasta sull'argomento interferenza confermata dalla correlazione neuro-occlusale ma il fenomeno si evince anche localmente proprio nel disco articolare. Uno altro studio di Cui SJ et al. ^[23]ha dimostrato sperimentalmente che l'effetto del sovraccarico meccanico sui dischi dell'ATM in un modello di interferenza occlusale di ratto in vivo, l'inibizione del potenziale vanilloide 4 del recettore transitorio meccanoinduttivo (TRPV4) ha alleviato la degenerazione del disco dell'ATM nel modello di interferenza occlusale del ratto.

In conclusione, come si spera di condividere, la questione è molto più complessa di quanto i clinici pensano e si affrettano ad eliminare le interferenze, per esempio, mediotrusive perchè se il carico indotto sull'articolazione, magari da una ipereccitabilità neuormotoria ( vedi capitolo Spasmo Emimasticatorio e Cavernosa Pineale) l'escursione mediotrusiva potrebbe essere un elemento protettivo magari a discapito del dente stesso.

Per questo motivo bisognerebbe rivalutare il termine 'Interferenza mediotrusiva'

In figura 9c e 9d il percorso mediotrusivo evidenziato con la carta di articolazione è stato costruito attraverso il calcolo dell'angolo determinato dalla Root-MEPs monolaterale che sposta la mandibola di circa 1/2mm su ciascun lato. Attraverso la programmazione dell'articolare Denar ( figura 10) si è potuto costruire una escursione con angoli diversi tra la ATM, molare e canino. Questo procedura genera un percorso naturale in cui il canino guida insieme alla mediotrusuone per proteggere la ATM dal carico masticatorio che esiste comunque al di là del bruxismo.