Difference between revisions of "Occlusion and Posture"

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{{ArtBy|autore=Gianni Frisardi}}
{{ArtBy|autore=Gianni Frisardi}}


=== Introduzione ===
=== Introduction ===
{{Bookind2}}
{{Bookind2}}Come introduzione alla sezione di capitoli riguardanti la 'Occlusione e Postura' possiamo riportare in parte una sintetica introduzione di Monika Nowak et al. <ref>Monika Nowak,,Joanna Golec, Aneta Wieczorek, and  Piotr Golec. Is There a Correlation between Dental Occlusion, Postural Stability and Selected Gait Parameters in Adults? Int J Environ Res Public Health. 2023 Jan; 20(2): 1652.  Published online 2023 Jan 16. doi: 10.3390/ijerph20021652. PMCID: PMC9862361. PMID: 36674407
Come introduzione alla sezione di capitoli riguardanti la 'Occlusione e Postura' possiamo riportare in parte una sintetica introduzione di Monika Nowak et al. <ref>Monika Nowak,,Joanna Golec, Aneta Wieczorek, and  Piotr Golec. Is There a Correlation between Dental Occlusion, Postural Stability and Selected Gait Parameters in Adults? Int J Environ Res Public Health. 2023 Jan; 20(2): 1652.  Published online 2023 Jan 16. doi: 10.3390/ijerph20021652. PMCID: PMC9862361. PMID: 36674407


</ref> su cui faremo le prime riflessioni concettuali segnalate dal nostro Linus pensieroso.
</ref> su cui faremo le prime riflessioni concettuali segnalate dal nostro Linus pensieroso.
As an introduction to the section of chapters concerning 'Occlusion and Posture' we can partially report a concise introduction by Monika Nowak et al.<ref>Monika Nowak,,Joanna Golec, Aneta Wieczorek, and  Piotr Golec. Is There a Correlation between Dental Occlusion, Postural Stability and Selected Gait Parameters in Adults? Int J Environ Res Public Health. 2023 Jan; 20(2): 1652.  Published online 2023 Jan 16. doi: 10.3390/ijerph20021652. PMCID: PMC9862361. PMID: 36674407
</ref> on which we will make the first conceptual reflections reported by our pensive Linus.
[[File:Question 2.jpg|center|50x50px]]
[[File:Question 2.jpg|center|50x50px]]


La postura è intesa come la posizione del corpo umano e il suo orientamento nello spazio che richiede l'analisi e l'integrazione degli stimoli provenienti da tre sistemi: visione, vestibolari e propriocezione.<ref>Guez G. The Posture. In: Kandel E., Schwartz J., editors. Principles of Neural Science. Elsevier; Amsterdam, The Netherlands: 1991. pp. 612–623.</ref><ref>Czaprowski D., Stoliński L., Tyrakowski M., Kozinoga M., Kotwicki T. Non-structural misalignments of body posture in the sagittal plane. Scoliosis Spinal Disord. 2018;13:6. doi: 10.1186/s13013-018-0151-5.</ref> Nel corso degli anni sono state fatte numerose osservazioni sui fattori che influenzano la stabilità posturale. <ref>Iwanenko J., Gurfinkel V. Human postural control. Front. Neurosci. 2018;12:17. </ref><ref>Guerraz M., Bronstein A.M. Ocular versus extraocular control of posture and equilibrium. Neurophysiol. Clin. 2008;38:391–398. doi: 10.1016/j.neucli.2008.09.007.</ref><ref>Hamaoui A., Frianta Y., Le Bozec S. Does increased muscular tension along the torso impair postural equilibrium in a standing posture? Gait Posture. 2011;34:457–461. doi: 10.1016/j.gaitpost.2011.06.017.</ref><ref>Kolar P., Sulc J., Kyncl M., Sanda J., Neuwirth J., Bokarius A.V., Kriz J., Kobesova A. Stabilizing function of the diaphragm: Dynamic MRI and synchronized spirometric assessment. J. Appl. Physiol. 2010;109:1064–1071. doi: 10.1152/japplphysiol.01216.2009.</ref><ref>Szczygieł E., Fudacz N., Golec J., Golec E. The impact of the position of the head on the functioning of the human body: A systematic review. Int. J. Occup. Med. Environ. Health. 2020;33:559–568. doi: 10.13075/ijomeh.1896.01585.</ref> Il ruolo del sistema craniomandibolare viene ora sempre più analizzato in relazione ad esso. <ref>Tardieu C., Dumitrescu M., Giraudeau A., Blanc J.L., Cheynet F., Borel L. Dental occlusion and postural control in adults. Neurosci. Lett. 2009;450:221–224. doi: 10.1016/j.neulet.2008.12.005.</ref><ref>Munhoz W.C., Hsing W.T. Interrelations between orthostatic postural deviations and subjects’ age, sex, malocclusion, and specific signs and symptoms of functional pathologies of the temporomandibular system: A preliminary correlation and regression study. Cranio. 2014;32:175–186. doi: 10.1179/0886963414Z.00000000031.</ref><ref>Pérez-Belloso A.J., Coheña-Jiménez M., Cabrera-Domínguez M.E., Galan-González A.F., Domínguez-Reyes A., Pabón-Carrasco M. Influence of dental malocclusion on body posture and foot posture in children: A cross-sectional study. Healthcare. 2020;8:485. doi: 10.3390/healthcare8040485.</ref><ref>Amaricai E., Onofrei R.R., Suciu O., Marcauteanu C., Stoica E.T., Negruțiu M.L., David V.L., Sinescu C. Do different dental conditions influence the static plantar pressure and stabilometry in young adults? PLoS ONE. 2020;15:e0228816. doi: 10.1371/journal.pone.0228816.</ref> Molte teorie tentano di spiegare l'associazione tra l'organo masticatorio e la postura, comprese le catene miofasciali, l'attivazione o la disattivazione del nervo trigemino e la successiva interazione nel tronco encefalico.<ref name=":0">Cabrera-Domínguez M.E., Domínguez-Reyes A., Pabón-Carrasco M., Pérez-Belloso A.J., Coheña-Jiménez M., Galán-González A.F. Dental malocclusion and its relation to the podal system. Front. Pediatr. 2021;9:654229. doi: 10.3389/fped.2021.654229.</ref><ref>Myers T.  Anatomy Trains: Myofasziale Leitbahnen (für Manual- und Bewegungstherapeuten) Elsevier Health Sciences; Berlin, Germany: 2015.</ref><ref>Pinganaud G., Bourcier F., Buisseret-Delmas C., Buisseret P. Primary trigeminal afferents to the vestibular nuclei in the rat: Existence of a collateral projection to the vestibulo-cerebellum. Neurosci. Lett. 1999;264:133–136. doi: 10.1016/S0304-3940(99)00179-2. [PubMed] [CrossRef] [Google Scholar] [Ref list]</ref> Tuttavia, questo è un argomento controverso nella comunità scientifica.  
Posture is understood as the position of the human body and its orientation in space which requires the analysis and integration of stimuli from three systems: vision, vestibular and proprioception.<ref>Guez G. The Posture. In: Kandel E., Schwartz J., editors. Principles of Neural Science. Elsevier; Amsterdam, The Netherlands: 1991. pp. 612–623.</ref><ref>Czaprowski D., Stoliński L., Tyrakowski M., Kozinoga M., Kotwicki T. Non-structural misalignments of body posture in the sagittal plane. Scoliosis Spinal Disord. 2018;13:6. doi: 10.1186/s13013-018-0151-5.</ref> Over the years, numerous observations have been made on the factors influencing postural stability. <ref>Iwanenko J., Gurfinkel V. Human postural control. Front. Neurosci. 2018;12:17. </ref><ref>Guerraz M., Bronstein A.M. Ocular versus extraocular control of posture and equilibrium. Neurophysiol. Clin. 2008;38:391–398. doi: 10.1016/j.neucli.2008.09.007.</ref><ref>Hamaoui A., Frianta Y., Le Bozec S. Does increased muscular tension along the torso impair postural equilibrium in a standing posture? Gait Posture. 2011;34:457–461. doi: 10.1016/j.gaitpost.2011.06.017.</ref><ref>Kolar P., Sulc J., Kyncl M., Sanda J., Neuwirth J., Bokarius A.V., Kriz J., Kobesova A. Stabilizing function of the diaphragm: Dynamic MRI and synchronized spirometric assessment. J. Appl. Physiol. 2010;109:1064–1071. doi: 10.1152/japplphysiol.01216.2009.</ref><ref>Szczygieł E., Fudacz N., Golec J., Golec E. The impact of the position of the head on the functioning of the human body: A systematic review. Int. J. Occup. Med. Environ. Health. 2020;33:559–568. doi: 10.13075/ijomeh.1896.01585.</ref> The role of the craniomandibular system is now being increasingly analyzed in relation to it. <ref>Tardieu C., Dumitrescu M., Giraudeau A., Blanc J.L., Cheynet F., Borel L. Dental occlusion and postural control in adults. Neurosci. Lett. 2009;450:221–224. doi: 10.1016/j.neulet.2008.12.005.</ref><ref>Munhoz W.C., Hsing W.T. Interrelations between orthostatic postural deviations and subjects’ age, sex, malocclusion, and specific signs and symptoms of functional pathologies of the temporomandibular system: A preliminary correlation and regression study. Cranio. 2014;32:175–186. doi: 10.1179/0886963414Z.00000000031.</ref><ref>Pérez-Belloso A.J., Coheña-Jiménez M., Cabrera-Domínguez M.E., Galan-González A.F., Domínguez-Reyes A., Pabón-Carrasco M. Influence of dental malocclusion on body posture and foot posture in children: A cross-sectional study. Healthcare. 2020;8:485. doi: 10.3390/healthcare8040485.</ref><ref>Amaricai E., Onofrei R.R., Suciu O., Marcauteanu C., Stoica E.T., Negruțiu M.L., David V.L., Sinescu C. Do different dental conditions influence the static plantar pressure and stabilometry in young adults? PLoS ONE. 2020;15:e0228816. doi: 10.1371/journal.pone.0228816.</ref> Many theories attempt to explain the association between the masticatory organ and posture, including myofascial chains, trigeminal nerve activation or deactivation, and subsequent interaction in the brainstem.<ref name=":0">Cabrera-Domínguez M.E., Domínguez-Reyes A., Pabón-Carrasco M., Pérez-Belloso A.J., Coheña-Jiménez M., Galán-González A.F. Dental malocclusion and its relation to the podal system. Front. Pediatr. 2021;9:654229. doi: 10.3389/fped.2021.654229.</ref><ref>Myers T.  Anatomy Trains: Myofasziale Leitbahnen (für Manual- und Bewegungstherapeuten) Elsevier Health Sciences; Berlin, Germany: 2015.</ref><ref>Pinganaud G., Bourcier F., Buisseret-Delmas C., Buisseret P. Primary trigeminal afferents to the vestibular nuclei in the rat: Existence of a collateral projection to the vestibulo-cerebellum. Neurosci. Lett. 1999;264:133–136. doi: 10.1016/S0304-3940(99)00179-2. [PubMed] [CrossRef] [Google Scholar] [Ref list]</ref> However, this is a controversial topic in the scientific community.  


Ci sono prove sia a sostegno di tale relazione<ref name=":1">Bracco P., Deregibus A., Piscetta R. Effects of different jaw relations on postural stability in human subjects. Neurosci. Lett. 2004;356:228–230. doi: 10.1016/j.neulet.2003.11.055.</ref><ref name=":2">Manfredini D., Castroflorio T., Perinetti G., Guarda-Nardini L. Dental occlusion, body posture and temporomandibular disorders: Where we are now and where we are heading for. J. Oral Rehabil. 2012;39:463–471. doi: 10.1111/j.1365-2842.2012.02291.x. </ref><ref name=":3">Sakaguchi K., Mehta N.R., Abdallah E.F., Forgione A.G., Hirayama H., Kawasaki T., Yokoyama A. Examination of the relationship between mandibular position and body posture. Cranio. 2007;25:237–249. doi: 10.1179/crn.2007.037. </ref><ref name=":4">Cuccia A., Caradonna C. The relationship between the stomatognathic system and body posture. Clinics. 2009;64:61–63. doi: 10.1590/S1807-59322009000100011.</ref><ref name=":5">Marchena-Rodríguez A., Moreno-Morales N., Ramírez-Parga E., Labajo-Manzanares M.T., Luque-Suárez A., Gijon-Nogueron G. Relationship between foot posture and dental malocclusions in children aged 6 to 9 years. A cross-sectional study. Medicine. 2018;97:e0701. doi: 10.1097/MD.0000000000010701</ref><ref name=":6">Iacob S.M., Chisnoiu A.M., Buduru S.D., Berar A., Fluerasu M.I., Iacob I., Objelean A., Studnicska W., Viman L.M. Plantar pressure variations induced by experimental malocclusion—A pilot case series study. Healthcare. 2021;9:599. doi: 10.3390/healthcare9050599.</ref> sia a confutazione.<ref name=":7">Michelotti A., Buonocore G., Farella M., Pellegrino G., Piergentili C., Altobelli S., Martina R. Postural stability and unilateral posterior crossbite: Is there a relationship? Neurosci. Lett. 2006;392:140–144. doi: 10.1016/j.neulet.2005.09.008.</ref><ref name=":8">Perinetti G., Contardo L., Silvestrini-Biavati A., Perdoni L., Castaldo A. Dental malocclusion and body posture in young subjects: A multiple regression study. Clinics. 2010;65:689–695. doi: 10.1590/S1807-59322010000700007.</ref><ref name=":9">Scharnweber B., Adjami F., Schuster G., Kopp S., Natrup J., Erbe C., Ohlendorf D. Influence of dental occlusion on postural control and plantar pressure distribution. Cranio. 2017;35:358–366. doi: 10.1080/08869634.2016.1244971.</ref><ref name=":10">Isaia B., Ravarotto M., Finotti P., Nogara M., Piran G., Gamberini J., Biz C., Masiero S., Frizziero A. Analysis of dental malocclusion and neuromotor control in young healthy subjects through new evaluation tools. J. Funct. Morphol. Kinesiol. 2019;4:5. doi: 10.3390/jfmk4010005.</ref>  
There is both evidence to support that relationship<ref name=":1">Bracco P., Deregibus A., Piscetta R. Effects of different jaw relations on postural stability in human subjects. Neurosci. Lett. 2004;356:228–230. doi: 10.1016/j.neulet.2003.11.055.</ref><ref name=":2">Manfredini D., Castroflorio T., Perinetti G., Guarda-Nardini L. Dental occlusion, body posture and temporomandibular disorders: Where we are now and where we are heading for. J. Oral Rehabil. 2012;39:463–471. doi: 10.1111/j.1365-2842.2012.02291.x. </ref><ref name=":3">Sakaguchi K., Mehta N.R., Abdallah E.F., Forgione A.G., Hirayama H., Kawasaki T., Yokoyama A. Examination of the relationship between mandibular position and body posture. Cranio. 2007;25:237–249. doi: 10.1179/crn.2007.037. </ref><ref name=":4">Cuccia A., Caradonna C. The relationship between the stomatognathic system and body posture. Clinics. 2009;64:61–63. doi: 10.1590/S1807-59322009000100011.</ref><ref name=":5">Marchena-Rodríguez A., Moreno-Morales N., Ramírez-Parga E., Labajo-Manzanares M.T., Luque-Suárez A., Gijon-Nogueron G. Relationship between foot posture and dental malocclusions in children aged 6 to 9 years. A cross-sectional study. Medicine. 2018;97:e0701. doi: 10.1097/MD.0000000000010701</ref><ref name=":6">Iacob S.M., Chisnoiu A.M., Buduru S.D., Berar A., Fluerasu M.I., Iacob I., Objelean A., Studnicska W., Viman L.M. Plantar pressure variations induced by experimental malocclusion—A pilot case series study. Healthcare. 2021;9:599. doi: 10.3390/healthcare9050599.</ref> and to refute it.<ref name=":7">Michelotti A., Buonocore G., Farella M., Pellegrino G., Piergentili C., Altobelli S., Martina R. Postural stability and unilateral posterior crossbite: Is there a relationship? Neurosci. Lett. 2006;392:140–144. doi: 10.1016/j.neulet.2005.09.008.</ref><ref name=":8">Perinetti G., Contardo L., Silvestrini-Biavati A., Perdoni L., Castaldo A. Dental malocclusion and body posture in young subjects: A multiple regression study. Clinics. 2010;65:689–695. doi: 10.1590/S1807-59322010000700007.</ref><ref name=":9">Scharnweber B., Adjami F., Schuster G., Kopp S., Natrup J., Erbe C., Ohlendorf D. Influence of dental occlusion on postural control and plantar pressure distribution. Cranio. 2017;35:358–366. doi: 10.1080/08869634.2016.1244971.</ref><ref name=":10">Isaia B., Ravarotto M., Finotti P., Nogara M., Piran G., Gamberini J., Biz C., Masiero S., Frizziero A. Analysis of dental malocclusion and neuromotor control in young healthy subjects through new evaluation tools. J. Funct. Morphol. Kinesiol. 2019;4:5. doi: 10.3390/jfmk4010005.</ref>  


==== Contenuti a sostegno della correlazione ====
==== Content supporting correlation ====




Gli autori dei rapporti scientifici, che riconoscono le associazioni tra i sistemi in questione, danno due indicazioni per le possibili interazioni. Il primo, cioè i disturbi ascendenti, si riferisce alla situazione in cui la cattiva postura e i disturbi delle strutture periferiche (es. arti inferiori), attraverso le attività neuromotorie  miofasciali e la dura madre condizionano funzionalmente le strutture cranio-mandibolari. Al contrario, una catena di disturbi discendenti è presente quando le anomalie della regione craniomandibolare interessano la postura e le aree del corpo che si trovano più distalmente, coinvolgendo anche il bacino e gli arti inferiori.<ref name=":0" /><ref name=":11">Michalakis K.X., Kamalakidis S.N., Pissiotis A.L., Hirayama H. The Effect of clenching and occlusal instability on body weight distribution, assessed by a postural platform. BioMed Res. Int. 2019;2019:7342541. doi: 10.1155/2019/7342541.</ref><ref name=":12">Julià-Sánchez S., Álvarez-Herms J., Cirer-Sastre R., Corbi F., Burtscher M. The influence of dental occlusion on dynamic balance and muscular tone. Front. Physiol. 2020;10:1626. doi: 10.3389/fphys.2019.01626.</ref><ref>Pacella E., Dari M., Giovannoni D., Mezio M., Caterini L., Costantini A. The relationship between occlusion and posture: A systematic review. Orthodontics. 2017;8:WMC005374.</ref> <blockquote>[[File:Question 2.jpg|left|50x50px]]E su questo nulla da dire perchè nessuno può negare una correlazione anatomo-funzionale tra sistemi vestibolari, cervelletto, sistema trigeminale e sistema neuromotorio periferico. Questa non è una opinione ma una constatazione scientifica dimostrata e riportata già in qualche parte di Masticationpedia.[[File:VEMP.jpg|thumb|200x200px|'''Figura 1:''' Vestibula Evoked Myogenic Potentials ( vedi capitolo '[[Sistemi Complessi]]']]I VEMP, tradotto in Potenziali Evocati Miocenici Vestibolari ne sono la dimostrazione. Gli stimoli acustici possono evocare risposte riflesse EMG nel muscolo massetere chiamate Vestibular Evoked Myogenic Potentials (VEMPs). Anche se questi risultati sono stati precedentemente attribuiti all'attivazione dei recettori cocleari (suono ad alta intensità), questi possono anche attivare i recettori vestibolari. Poiché studi anatomici e fisiologici, sia negli animali che nell'uomo, hanno dimostrato che i muscoli masseteri sono un bersaglio per gli ingressi vestibolari, gli autori di questo studio hanno rivalutato il contributo vestibolare per i riflessi masseterici. Questo è un tipico esempio di 'Sistema Complesso' di livello base in quanto consiste di due soli sistemi nervosi cranici ma, allo stesso tempo, interagiscono attivando circuiti mono e polisinaptici (Figura 1).</blockquote>Precedenti pubblicazioni che tentano di valutare l'impatto delle anomalie craniofacciali sulla postura e sulla stabilità si concentrano, tra l'altro, sull'analisi dei pazienti che presentano sintomi di disturbi temporo-mandibolari. È stato dimostrato che i cambiamenti nell'articolazione temporomandibolare (ATM) possono avere un impatto diretto sull'attività muscolare in termini di postura, stabilità e prestazioni fisiche.<ref name=":2" /><ref>Moon H.J., Lee Y.K. The relationship between dental occlusion/temporomandibular joint status and general body health: Part 1. Dental occlusion and TMJ status exert an influence on general body health. J. Altern. Complement. Med. 2011;17:995–1000. doi: 10.1089/acm.2010.0739.</ref><ref>Souza J.A., Pasinato F., Correa E.A., da Silva A.M. Global body posture and plantar pressure distribution in individuals with and without temporomandibular disorder: A preliminary study. J. Manip. Physiol. Ther. 2014;37:407–414.</ref>  Tuttavia, viene evidenziata la mancanza di studi di alta qualità che utilizzino strumenti di misurazione avanzati per comprendere meglio il fenomeno in esame.<ref>Ferrillo M., Marotta N., Giudice A., Calafiore D., Curci C., Fortunato L., Ammendolia A., de Sire A. Effects of occlusal splints on spinal posture in patients with temporomandibular disorders: A systematic review. Healthcare. 2022;10:739. doi: 10.3390/healthcare10040739.</ref>  
The authors of the scientific reports, who recognize the associations between the systems in question, give two indications for the possible interactions. The first, i.e. ascending disturbances, refers to the situation in which bad posture and disturbances of the peripheral structures (e.g. lower limbs), through myofascial neuromotor activities and the dura mater, functionally condition the cranio-mandibular structures. Conversely, a chain of descending disorders is present when anomalies of the craniomandibular region affect posture and body areas located more distally, including the pelvis and lower extremities.<ref name=":0" /><ref name=":11">Michalakis K.X., Kamalakidis S.N., Pissiotis A.L., Hirayama H. The Effect of clenching and occlusal instability on body weight distribution, assessed by a postural platform. BioMed Res. Int. 2019;2019:7342541. doi: 10.1155/2019/7342541.</ref><ref name=":12">Julià-Sánchez S., Álvarez-Herms J., Cirer-Sastre R., Corbi F., Burtscher M. The influence of dental occlusion on dynamic balance and muscular tone. Front. Physiol. 2020;10:1626. doi: 10.3389/fphys.2019.01626.</ref><ref>Pacella E., Dari M., Giovannoni D., Mezio M., Caterini L., Costantini A. The relationship between occlusion and posture: A systematic review. Orthodontics. 2017;8:WMC005374.</ref> <blockquote>[[File:Question 2.jpg|left|50x50px]]And on this nothing to say because no one can deny an anatomical-functional correlation between vestibular systems, cerebellum, trigeminal system and peripheral neuromotor system. This is not an opinion but a proven scientific observation already reported somewhere in Masticationpedia.[[File:VEMP.jpg|thumb|200x200px|Figure 1: Vestibula Evoked Myogenic Potentials (see chapter '[[Complex Systems]]']]VEMPs, translated into Miocene Vestibular Evoked Potentials are proof of this. Acoustic stimuli can evoke EMG reflex responses in the masseter muscle called Vestibular Evoked Myogenic Potentials (VEMPs). Although these findings have previously been attributed to activation of cochlear (high-intensity sound) receptors, these may also activate vestibular receptors. Because anatomical and physiological studies in both animals and humans have demonstrated that the masseter muscles are a target for vestibular inputs, the authors of this study reevaluated the vestibular contribution for masseter reflexes. This is a typical example of a basic level 'Complex System' as it consists of only two cranial nervous systems but, at the same time, they interact by activating monosynaptic and polysynaptic circuits (Figure 1).</blockquote>Previous publications attempting to evaluate the impact of craniofacial abnormalities on posture and stability focus, among others, on the analysis of patients presenting with symptoms of temporomandibular disorders. It has been shown that changes in the temporomandibular joint (TMJ) can have a direct impact on muscle activity in terms of posture, stability and physical performance.<ref name=":2" /><ref>Moon H.J., Lee Y.K. The relationship between dental occlusion/temporomandibular joint status and general body health: Part 1. Dental occlusion and TMJ status exert an influence on general body health. J. Altern. Complement. Med. 2011;17:995–1000. doi: 10.1089/acm.2010.0739.</ref><ref>Souza J.A., Pasinato F., Correa E.A., da Silva A.M. Global body posture and plantar pressure distribution in individuals with and without temporomandibular disorder: A preliminary study. J. Manip. Physiol. Ther. 2014;37:407–414.</ref>  However, there is a lack of high-quality studies using advanced measurement tools to better understand the phenomenon under investigation.<ref>Ferrillo M., Marotta N., Giudice A., Calafiore D., Curci C., Fortunato L., Ammendolia A., de Sire A. Effects of occlusal splints on spinal posture in patients with temporomandibular disorders: A systematic review. Healthcare. 2022;10:739. doi: 10.3390/healthcare10040739.</ref> The study authors evaluated the impact of masticatory abnormalities on postural control and focuses on evaluating individuals with specific malocclusions that determine the anteroposterior position of the mandible. According to some researchers, malocclusion, like TMD, can affect the osteoarticular system of the whole body and become a source of persistent pain and favor the development and perpetuation of some postural defects. According to the cited authors, occlusal disturbances can lead to an altered stimulation of the periodontal proprioceptors, causing changes in the tension of the neck muscles and postural muscles and changes in the position of the head, followed by compensatory changes in the anatomical regions in their immediate vicinity. Over time, this can affect your posture, center of gravity position, or foot contact with the ground.<ref name=":0" /><ref name=":11" /><ref name=":12" /><ref>Saccucci M., Tettamanti L., Mummolo S., Polimeni A., Festa F., Tecco S. Scoliosis and dental occlusion: A review of the literature. Scoliosis. 2011;6:1–15. doi: 10.1186/1748-7161-6-15. </ref><ref>Sforza C., Tartaglia G.M., Solimene U., Morgan V., Kaspranskiy R.R., Ferrario V.F. Occlusion, sternocleidomastoid muscle activity, and body sway: A pilot study in male astronauts. Cranio. 2006;24:43–49. doi: 10.1179/crn.2006.008</ref><blockquote>[[File:Question 2.jpg|left|50x50px]][[File:Pz.Arc006.jpg|thumb|232x232px|'''Figure 2:'''Trigeminal electrophysiological responses.]]This could also be true but at the same time it should be demonstrable in order not to make diagnostic errors such as the one we will present in the section dedicated to 'Occlusion and Posture. Indeed, the patient we will present exclusively reported a masticatory disorder such as to require continuous rehabilitative reconstructions from his dentist. How can we demonstrate this occlusal disturbance at the neuromotor level such that it can also condition the vestibular system, the cerebellum and other brain centres? Faced with a marked asymmetry such as the one shown in Figure 2, we certainly cannot deny a trigeminal disorder which is often related to a malocclusion. In Figure 2A we can see a slight asymmetry of the interferential EMG trace between the right and left masseter as well as the MEPs of the trigeminal root (Figure 2B) as well as the absence of the action potential on the right masseter in the mandibular reflex responses (Figure 2C ). As we will see in the chapters concerning this patient, these abnormal trigeminal electrophysiological responses have nothing to do with occlusal disturbances, much less postural disturbances.</blockquote>However, there is still a gap in scientific knowledge on the relationship between craniofacial structure and spinal postural control in patients with malocclusion. Furthermore, the available documents show problems related to the small number of subjects, the small number of tested parameters or the selection of reliable measurement tools.<ref name=":8" /><ref>Michelotti A., Buonocore G., Manzo P., Pellegrino G., Farella M. Dental occlusion and posture: An overview. Prog. Orthod. 2011;12:53–58. doi: 10.1016/j.pio.2010.09.010. </ref><ref>Ishizawa T., Xu H., Onodera K., Ooya K. Weight distributions on soles of feet in the primary and early permanent dentition with normal occlusion. J. Clin. Pediatr. Dent. 2005;30:165–168. doi: 10.17796/jcpd.30.2.8x4727137678061m.</ref>


Gli autori dello studio hanno valutato l'impatto delle anomalie masticatorie sul controllo posturale e si concentra sulla valutazione di individui con malocclusioni specifiche che determinano la posizione anteroposteriore della mandibola. Secondo alcuni ricercatori, la malocclusione, come la TMD, può colpire il sistema osteoarticolare di tutto il corpo e diventare fonte di dolore persistente e favorire lo sviluppo e la perpetuazione di alcuni difetti posturali. Secondo gli autori citati, i disturbi occlusali possono comportare un'alterata stimolazione dei propriocettori parodontali, provocando modificazioni della tensione dei muscoli del collo e dei muscoli posturali e modificazioni della posizione della testa, seguite da modificazioni compensatorie delle regioni anatomiche nelle loro immediate vicinanze. Nel tempo, questo può influenzare la postura, la posizione del baricentro o il contatto del piede con il suolo.<ref name=":0" /><ref name=":11" /><ref name=":12" /><ref>Saccucci M., Tettamanti L., Mummolo S., Polimeni A., Festa F., Tecco S. Scoliosis and dental occlusion: A review of the literature. Scoliosis. 2011;6:1–15. doi: 10.1186/1748-7161-6-15. </ref><ref>Sforza C., Tartaglia G.M., Solimene U., Morgan V., Kaspranskiy R.R., Ferrario V.F. Occlusion, sternocleidomastoid muscle activity, and body sway: A pilot study in male astronauts. Cranio. 2006;24:43–49. doi: 10.1179/crn.2006.008</ref><blockquote>[[File:Question 2.jpg|left|50x50px]][[File:Pz.Arc006.jpg|thumb|232x232px|'''Figura 2:''' Risposte elettrofisiologiche trigeminali.]]Ciò potrebbe anche essere vero ma contestualmente dovrebbe essere dimostrabile per non incombere in errori diagnostici come quello che presenteremo nel corso della sezione dedicata alla 'Occlusione e Postura. Il paziente che presenteremo, effettivamente, riferiva esclusivamente un disturbo masticatorio tale da richiedere continui rifacimenti riabilitativi al proprio dentista. Come possiamo dare prova di questo disturbo occlusale al livello neuromotorio tale che possa condizionare anche il sistema vestibolare, il cervelletto ed altre Centri Cerebrali? Di fronte ad una asimmetria marcata come quella mostrata in Figura 2 non possiamo, certamente, negare un disturbo trigeminale che spesso è correlato ad una malocclusione. In Figura 2A si può notare una lieve asimmetria del tracciato EMG interferenziale tra il massetere destro e sinistro cose pure dei MEP della radice trigeminale (Figura 2B)tanto quanto l'assenza del potenziale d'azione sul massetere destro nelle risposte riflesse mandibolari ( Figura 2C). Come vedremo nei capitoli che riguardano questo paziente queste risposte abnormi elettrofisiologie trigeminali non hanno nulla a che vedere con i disturbi occlusale tanto meno dei disturbi della postura.</blockquote>Tuttavia, esiste ancora una lacuna nelle conoscenze scientifiche sulla relazione tra struttura craniofacciale e controllo posturale spinale nei pazienti con malocclusione. Inoltre, i documenti disponibili mostrano problemi legati al numero ridotto di soggetti, al numero ridotto di parametri testati o alla selezione di strumenti di misurazione affidabili.<ref name=":8" /><ref>Michelotti A., Buonocore G., Manzo P., Pellegrino G., Farella M. Dental occlusion and posture: An overview. Prog. Orthod. 2011;12:53–58. doi: 10.1016/j.pio.2010.09.010. </ref><ref>Ishizawa T., Xu H., Onodera K., Ooya K. Weight distributions on soles of feet in the primary and early permanent dentition with normal occlusion. J. Clin. Pediatr. Dent. 2005;30:165–168. doi: 10.17796/jcpd.30.2.8x4727137678061m.</ref>
Malocclusion, which these studies focus on, can result from abnormalities in the structure and alignment of the bones of the jaw and mandible in relation to each other or from an abnormal arrangement of the dental arches.


La malocclusione, su cui si concentrano questi studi, può derivare da anomalie nella struttura e nell'allineamento delle ossa della mascella e della mandibola in relazione tra loro o da una disposizione anormale delle arcate dentarie.
Angle suggested a classification of occlusion and malocclusion based on the anteroposterior position of the first molar and the position of the canines.<ref>Bernabé E., Sheiham A., de Oliveira C.M. Condition-specific impacts on quality of life attributed to malocclusion by adolescents with normal occlusion and Class I, II and III malocclusion. Angle Orthod. 2008;78:977–982. doi: 10.2319/091707-444.1</ref><ref name=":13">Okeson J.P.  Management of Temporomandibular Disorders and Occlusion.Mosby; Maryland Heights, MO, USA: 2019.</ref>Malocclusion is often a congenital condition, resulting from hereditary or environmental factors. It is also caused by local factors, such as an abnormal pattern of breathing or postural defects, as well as oral parafunctions such as nail biting or teeth grinding (bruxism).<ref name=":13" />According to Lombardo's analyses, occlusal anomalies occur on average in 56% of the general population.<ref name=":14">Lombardo G., Vena F., Negr P., Pagano S., Barilotti C., Paglia L., Colombo S., Orso M., Cianetti S. Worldwide prevalence of malocclusion in the different stages of dentition: A systematic review and meta-analysis. Eur. J. Paediatr. Dent. 2020;21:115–122.</ref> Their prevalence increases with age. Given their increasing prevalence in later age groups and the consequences they entail, it is reasonable to expect a large number of adult patients who will require complex and expensive multidisciplinary treatment.<ref name=":14" /><ref>Kawala B., Szumielewicz M., Kozanecka A. Are orthodontists still needed? Epidemiology of malocclusion among polish children and teenagers in last 15 years. Dent. Med. Probl. 2009;46:273–278</ref><blockquote>[[File:Question 2.jpg|left|50x50px]][[File:Recovery cycle.jpeg|thumb|150x150px|Figura 3: <sub>rc</sub>MIR in paziente bruxista]]Regarding bruxism<ref name=":13" /> we certainly cannot speak of scientific certainties or take into consideration the incidence of bruxism in the population because, as described in the specific chapter concerning our patient 'Bruxer', he had a perfect occlusion and neuromuscular responses apparently up to standard if it hadn't been for the study of the case and have highlighted a neuronal hyperexcitability with the test of the crMIR masseter inhibitory recovery cycle (Figure 3). Although the patient was in a state of neuronal hyperexcitability which affected the entire left leg with stiffness of the upper limbs, he never accused postulated problems. With this we want to underline that although there are correlations between different cerebral association areas such as the vestibular, the trigeminal, the midbrain and so on, this does not give the clinician the right to base the diagnosis on these certainties. As, of course, we will repeat repeatedly throughout the 'Normal Science' section to justify the next section which will focus on the aspect of the anomalies and therefore the crisis of the paradigm.</blockquote>


Angle ha suggerito una classificazione di occlusione e malocclusione basata sulla posizione anteroposteriore del primo molare e sulla posizione dei canini.<ref>Bernabé E., Sheiham A., de Oliveira C.M. Condition-specific impacts on quality of life attributed to malocclusion by adolescents with normal occlusion and Class I, II and III malocclusion. Angle Orthod. 2008;78:977–982. doi: 10.2319/091707-444.1</ref><ref name=":13">Okeson J.P.  Management of Temporomandibular Disorders and Occlusion.Mosby; Maryland Heights, MO, USA: 2019.</ref>La malocclusione è spesso una condizione congenita, derivante da fattori ereditari o ambientali. È anche causato da fattori locali, come un modello anormale di respirazione o difetti posturali, nonché parafunzioni orali come mangiarsi le unghie o digrignare i denti (bruxismo).<ref name=":13" /> Secondo le analisi di Lombardo, le anomalie occlusali si verificano in media nel 56% della popolazione generale.<ref name=":14">Lombardo G., Vena F., Negr P., Pagano S., Barilotti C., Paglia L., Colombo S., Orso M., Cianetti S. Worldwide prevalence of malocclusion in the different stages of dentition: A systematic review and meta-analysis. Eur. J. Paediatr. Dent. 2020;21:115–122.</ref> La loro prevalenza aumenta con l'età. Dato l'aumento della loro prevalenza nei gruppi di età successivi e le conseguenze che comportano, è ragionevole aspettarsi un gran numero di pazienti adulti che necessiteranno di un trattamento multidisciplinare complesso e costoso.<ref name=":14" /><ref>Kawala B., Szumielewicz M., Kozanecka A. Are orthodontists still needed? Epidemiology of malocclusion among polish children and teenagers in last 15 years. Dent. Med. Probl. 2009;46:273–278</ref><blockquote>[[File:Question 2.jpg|left|50x50px]][[File:Recovery cycle.jpeg|thumb|150x150px|Figura 3: <sub>rc</sub>MIR in paziente bruxista]]Riguardo il bruxismo<ref name=":13" /> non possiamo certamente parlare di certezze scientifiche o prendere in considerazione l'incidenza del bruxismo nella popolazione perchè come descritto nel capitolo specifico riguardante il nostro paziente '[[Codice criptato: Ipereccitabilità del sistema trigeminale|Bruxer]]' aveva una occlusione perfetta e risposte neuromuscolari apparentemente a norma se non fosse stato per l'approfondimento dello studio del caso ed aver evidenziato una ipereccitabilità neuronale con il test del ciclo di recupero inibitorio masseterino <sub>cr</sub>MIR (Figura 3). Nonostante il paziente era in uno stato di ipereccitabilità neuronale che prendeva l'intero emulato sinistro con rigidità degli arti superiori non ha mai accusato problemi postulai. Con questo si vuole sottolineare che nonostante ci siano delle correlazione tra diverse aree associative cerebrali quali la vestibolare, la trigeminale, il mesencefalo e quant'altro ciò non dà diritto al clinico di fondare su queste certezza la diagnosi. Come, ovviamente, riporteremo ripetutamente per tutta la sezione 'Scienza Normale' per giustificare la sezione successiva che si soffermerà sull'aspetto delle anomalie e dunque della crisi del paradigma.</blockquote>
Given the high proportion of patients with malocclusions <ref name=":5" /><ref name=":6" /> and the conflicting reports of these reports, <ref name=":1" /><ref name=":2" /><ref name=":3" /><ref name=":4" /><ref name=":5" /><ref name=":6" /><ref name=":7" /><ref name=":8" /><ref name=":9" /><ref name=":10" /> the need for further knowledge and analysis of individual malocclusions and associated musculoskeletal abnormalities under dynamic and static conditions is reasonable.  


There is still a lack of research on the effect of occlusion on postural stability and plantar pressure distribution during standing and walking in the same group of adults with Angle Class I, II, and III.


Data l'elevata percentuale di pazienti con malocclusione <ref name=":5" /><ref name=":6" /> e le segnalazioni contraddittorie circa le relazioni in questione, <ref name=":1" /><ref name=":2" /><ref name=":3" /><ref name=":4" /><ref name=":5" /><ref name=":6" /><ref name=":7" /><ref name=":8" /><ref name=":9" /><ref name=":10" /> la necessità di ulteriori conoscenze e l'analisi delle malocclusioni individuali e delle anomalie muscoloscheletriche associate in condizioni dinamiche e statiche è ragionevole.  
==== Contents to refute the correlation ====
As far as the authors contesting the correlation between occlusion and posture are concerned, we can report the results of Giuseppe Perinetti et al.<ref name=":8" /> of 122 subjects, including 86 males and 36 females (age range 10.8 to 16.3 years) who tested negative for temporomandibular disorders or other conditions affecting the stomatognathic systems, with the exception of malocclusion. An assessment of dental occlusion included dentition stage, molar class, overjet, overbite, anterior and posterior crossbite, scissor bite, mandibular crowding, and dental midline deviation. Furthermore, body posture was recorded through static posturography using a vertical force platform. Recordings were performed under two conditions:


C'è ancora una mancanza di ricerca sull'effetto dell'occlusione sulla stabilità posturale e sulla distribuzione della pressione plantare durante la posizione eretta e la deambulazione nello stesso gruppo di adulti con Angle Class I, II e III.  
# mandibular rest position (RP)
#dental intercuspid position (ICP).  


==== Contenuti a confutazione della correlazione ====
The conclusion was that all posturographic parameters showed great variability and were very similar between recording conditions. Furthermore, a limited number of weakly significant correlations, mainly for the overbite phase, were observed when using multivariate models.
Per quanto riguarda gli autori che contestano la correlazione tra Occlusione e postura possiamo riportare i risultati di Giuseppe Perinetti et al.<ref name=":8" /> su 122 soggetti, inclusi 86 maschi e 36 femmine (fascia di età compresa tra 10,8 e 16,3 anni) risultati negativi per disordini temporomandibolari o altre condizioni che interessano i sistemi stomatognatici, ad eccezione della malocclusione. Una valutazione dell'occlusione dentale ha incluso fase della dentatura, classe molare, overjet, overbite, crossbite anteriore e posteriore, scissorbite, affollamento mandibolare e deviazione della linea mediana dentale. Inoltre, la postura del corpo è stata registrata attraverso la posturografia statica utilizzando una piattaforma di forza verticale. Le registrazioni sono state eseguite in due condizioni, vale a dire


# posizione di riposo mandibolare (RP)
The author's current findings were that regarding the use of posturography as a diagnostic aid for subjects affected by dental malocclusion, they do not support the existence of clinically relevant correlations between malocclusion typology and body posture.
# posizione intercuspidale dentale (ICP).  


La conclusione fu che tutti i parametri posturografici presentavano una grande variabilità ed erano molto simili tra le condizioni di registrazione. Inoltre, è stato osservato un numero limitato di correlazioni debolmente significative, principalmente per la fase di overbite, quando si utilizzano modelli multivariati.
Another interesting article in the group contesting the correlation comes from Benjamin Scharnweber et al.<ref name=":9" /> examined 87 male subjects with a mean age of 25.23 ± 3.5 years (18 to 35 years). The dental models of the subjects were analyzed. Postural control and plantar pressure distribution were recorded from a weight bearing platform. Possible orthodontic and orthopedic influencing factors were determined from a medical history or questionnaire. All tests performed were randomized and repeated three times each for intercuspid position (ICP) and locked occlusion (BO).  


I risultati attuali dell'autore furono che riguarda l'uso della posturografia come ausilio diagnostico per i soggetti affetti da malocclusione dentale, non supportano l'esistenza di correlazioni clinicamente rilevanti tratipologiwa di malocclusione e postura corporea.
In this study, the ICP occlusal position was found to increase body sway in the frontal (p ≤ 0.01) and sagittal (p ≤ 0.03) planes compared to the BO position, whereas all other 29 correlations were independent of position of the occlusion.


Un altro interessante articolo nel gruppo contestano la correlazione viene da Benjamin Scharnweber et al.<ref name=":9" /> ha esaminati 87 soggetti maschi con un'età media di 25,23 ± 3,5 anni (da 18 a 35 anni). Sono stati analizzati i modelli dentali dei soggetti. Il controllo posturale e la distribuzione della pressione plantare sono stati registrati da una piattaforma di carico. Possibili fattori di influenza ortodontici e ortopedici sono stati determinati da un'anamnesi o da un questionario. Tutti i test eseguiti sono stati randomizzati e ripetuti tre volte ciascuno per la posizione intercuspidale (ICP) e l'occlusione bloccata (BO).  
For both ICP or BO cases, angle therapy, midline shift, crossbite, or orthodontic therapy was found to have no influence on postural control or plantar pressure distribution (p > 0.05).


In questo studio è risultato che la posizione occlusale ICP aumenta l'oscillazione del corpo nei piani frontale (p ≤ 0,01) e sagittale (p ≤ 0,03) rispetto alla posizione BO, mentre tutte le altre 29 correlazioni erano indipendenti dalla posizione dell'occlusione.  
In conclusion, the author confirms that persistent dental parameters have no effect on postural sway. Furthermore, postural control and plantar pressure distribution were found to be independent postural criteria.


Per entrambi i casi ICP o BO, è stato riscontrato che la terapia angolare, lo spostamento della linea mediana, il morso incrociato o la terapia ortodontica non hanno alcuna influenza sul controllo posturale o sulla distribuzione della pressione plantare (p > 0,05).
{{q2|After this due introduction to the 'Occlusion and Posture' section we can move on to the specific chapter concerning a patient with evident postulai problems.}}{{Bib}}
 
In conclusione l'autore conferma che parametri dentali persistenti non hanno alcun effetto sull'oscillazione posturale. Inoltre, il controllo posturale e la distribuzione della pressione plantare sono risultati essere criteri posturali indipendenti.{{q2|Dopo questa dovuta introduzione alla sezione di 'Occlusione e Postura' possiamo passare al capitolo specifico riguardante un paziente con evidenti problemi postulai.}}{{Bib}}


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Masticationpedia
Article by  Gianni Frisardi

 

Introduction

Come introduzione alla sezione di capitoli riguardanti la 'Occlusione e Postura' possiamo riportare in parte una sintetica introduzione di Monika Nowak et al. [1] su cui faremo le prime riflessioni concettuali segnalate dal nostro Linus pensieroso.

As an introduction to the section of chapters concerning 'Occlusion and Posture' we can partially report a concise introduction by Monika Nowak et al.[2] on which we will make the first conceptual reflections reported by our pensive Linus.

Question 2.jpg

Posture is understood as the position of the human body and its orientation in space which requires the analysis and integration of stimuli from three systems: vision, vestibular and proprioception.[3][4] Over the years, numerous observations have been made on the factors influencing postural stability. [5][6][7][8][9] The role of the craniomandibular system is now being increasingly analyzed in relation to it. [10][11][12][13] Many theories attempt to explain the association between the masticatory organ and posture, including myofascial chains, trigeminal nerve activation or deactivation, and subsequent interaction in the brainstem.[14][15][16] However, this is a controversial topic in the scientific community.

There is both evidence to support that relationship[17][18][19][20][21][22] and to refute it.[23][24][25][26]

Content supporting correlation

The authors of the scientific reports, who recognize the associations between the systems in question, give two indications for the possible interactions. The first, i.e. ascending disturbances, refers to the situation in which bad posture and disturbances of the peripheral structures (e.g. lower limbs), through myofascial neuromotor activities and the dura mater, functionally condition the cranio-mandibular structures. Conversely, a chain of descending disorders is present when anomalies of the craniomandibular region affect posture and body areas located more distally, including the pelvis and lower extremities.[14][27][28][29]

Question 2.jpg

And on this nothing to say because no one can deny an anatomical-functional correlation between vestibular systems, cerebellum, trigeminal system and peripheral neuromotor system. This is not an opinion but a proven scientific observation already reported somewhere in Masticationpedia.

Figure 1: Vestibula Evoked Myogenic Potentials (see chapter 'Complex Systems'

VEMPs, translated into Miocene Vestibular Evoked Potentials are proof of this. Acoustic stimuli can evoke EMG reflex responses in the masseter muscle called Vestibular Evoked Myogenic Potentials (VEMPs). Although these findings have previously been attributed to activation of cochlear (high-intensity sound) receptors, these may also activate vestibular receptors. Because anatomical and physiological studies in both animals and humans have demonstrated that the masseter muscles are a target for vestibular inputs, the authors of this study reevaluated the vestibular contribution for masseter reflexes. This is a typical example of a basic level 'Complex System' as it consists of only two cranial nervous systems but, at the same time, they interact by activating monosynaptic and polysynaptic circuits (Figure 1).

Previous publications attempting to evaluate the impact of craniofacial abnormalities on posture and stability focus, among others, on the analysis of patients presenting with symptoms of temporomandibular disorders. It has been shown that changes in the temporomandibular joint (TMJ) can have a direct impact on muscle activity in terms of posture, stability and physical performance.[18][30][31] However, there is a lack of high-quality studies using advanced measurement tools to better understand the phenomenon under investigation.[32] The study authors evaluated the impact of masticatory abnormalities on postural control and focuses on evaluating individuals with specific malocclusions that determine the anteroposterior position of the mandible. According to some researchers, malocclusion, like TMD, can affect the osteoarticular system of the whole body and become a source of persistent pain and favor the development and perpetuation of some postural defects. According to the cited authors, occlusal disturbances can lead to an altered stimulation of the periodontal proprioceptors, causing changes in the tension of the neck muscles and postural muscles and changes in the position of the head, followed by compensatory changes in the anatomical regions in their immediate vicinity. Over time, this can affect your posture, center of gravity position, or foot contact with the ground.[14][27][28][33][34]

Question 2.jpg
Figure 2:Trigeminal electrophysiological responses.

This could also be true but at the same time it should be demonstrable in order not to make diagnostic errors such as the one we will present in the section dedicated to 'Occlusion and Posture. Indeed, the patient we will present exclusively reported a masticatory disorder such as to require continuous rehabilitative reconstructions from his dentist. How can we demonstrate this occlusal disturbance at the neuromotor level such that it can also condition the vestibular system, the cerebellum and other brain centres? Faced with a marked asymmetry such as the one shown in Figure 2, we certainly cannot deny a trigeminal disorder which is often related to a malocclusion. In Figure 2A we can see a slight asymmetry of the interferential EMG trace between the right and left masseter as well as the MEPs of the trigeminal root (Figure 2B) as well as the absence of the action potential on the right masseter in the mandibular reflex responses (Figure 2C ). As we will see in the chapters concerning this patient, these abnormal trigeminal electrophysiological responses have nothing to do with occlusal disturbances, much less postural disturbances.

However, there is still a gap in scientific knowledge on the relationship between craniofacial structure and spinal postural control in patients with malocclusion. Furthermore, the available documents show problems related to the small number of subjects, the small number of tested parameters or the selection of reliable measurement tools.[24][35][36]

Malocclusion, which these studies focus on, can result from abnormalities in the structure and alignment of the bones of the jaw and mandible in relation to each other or from an abnormal arrangement of the dental arches.

Angle suggested a classification of occlusion and malocclusion based on the anteroposterior position of the first molar and the position of the canines.[37][38]Malocclusion is often a congenital condition, resulting from hereditary or environmental factors. It is also caused by local factors, such as an abnormal pattern of breathing or postural defects, as well as oral parafunctions such as nail biting or teeth grinding (bruxism).[38]According to Lombardo's analyses, occlusal anomalies occur on average in 56% of the general population.[39] Their prevalence increases with age. Given their increasing prevalence in later age groups and the consequences they entail, it is reasonable to expect a large number of adult patients who will require complex and expensive multidisciplinary treatment.[39][40]

Question 2.jpg
Figura 3: rcMIR in paziente bruxista

Regarding bruxism[38] we certainly cannot speak of scientific certainties or take into consideration the incidence of bruxism in the population because, as described in the specific chapter concerning our patient 'Bruxer', he had a perfect occlusion and neuromuscular responses apparently up to standard if it hadn't been for the study of the case and have highlighted a neuronal hyperexcitability with the test of the crMIR masseter inhibitory recovery cycle (Figure 3). Although the patient was in a state of neuronal hyperexcitability which affected the entire left leg with stiffness of the upper limbs, he never accused postulated problems. With this we want to underline that although there are correlations between different cerebral association areas such as the vestibular, the trigeminal, the midbrain and so on, this does not give the clinician the right to base the diagnosis on these certainties. As, of course, we will repeat repeatedly throughout the 'Normal Science' section to justify the next section which will focus on the aspect of the anomalies and therefore the crisis of the paradigm.

Given the high proportion of patients with malocclusions [21][22] and the conflicting reports of these reports, [17][18][19][20][21][22][23][24][25][26] the need for further knowledge and analysis of individual malocclusions and associated musculoskeletal abnormalities under dynamic and static conditions is reasonable.

There is still a lack of research on the effect of occlusion on postural stability and plantar pressure distribution during standing and walking in the same group of adults with Angle Class I, II, and III.

Contents to refute the correlation

As far as the authors contesting the correlation between occlusion and posture are concerned, we can report the results of Giuseppe Perinetti et al.[24] of 122 subjects, including 86 males and 36 females (age range 10.8 to 16.3 years) who tested negative for temporomandibular disorders or other conditions affecting the stomatognathic systems, with the exception of malocclusion. An assessment of dental occlusion included dentition stage, molar class, overjet, overbite, anterior and posterior crossbite, scissor bite, mandibular crowding, and dental midline deviation. Furthermore, body posture was recorded through static posturography using a vertical force platform. Recordings were performed under two conditions:

  1. mandibular rest position (RP)
  2. dental intercuspid position (ICP).

The conclusion was that all posturographic parameters showed great variability and were very similar between recording conditions. Furthermore, a limited number of weakly significant correlations, mainly for the overbite phase, were observed when using multivariate models.

The author's current findings were that regarding the use of posturography as a diagnostic aid for subjects affected by dental malocclusion, they do not support the existence of clinically relevant correlations between malocclusion typology and body posture.

Another interesting article in the group contesting the correlation comes from Benjamin Scharnweber et al.[25] examined 87 male subjects with a mean age of 25.23 ± 3.5 years (18 to 35 years). The dental models of the subjects were analyzed. Postural control and plantar pressure distribution were recorded from a weight bearing platform. Possible orthodontic and orthopedic influencing factors were determined from a medical history or questionnaire. All tests performed were randomized and repeated three times each for intercuspid position (ICP) and locked occlusion (BO).

In this study, the ICP occlusal position was found to increase body sway in the frontal (p ≤ 0.01) and sagittal (p ≤ 0.03) planes compared to the BO position, whereas all other 29 correlations were independent of position of the occlusion.

For both ICP or BO cases, angle therapy, midline shift, crossbite, or orthodontic therapy was found to have no influence on postural control or plantar pressure distribution (p > 0.05).

In conclusion, the author confirms that persistent dental parameters have no effect on postural sway. Furthermore, postural control and plantar pressure distribution were found to be independent postural criteria.

«After this due introduction to the 'Occlusion and Posture' section we can move on to the specific chapter concerning a patient with evident postulai problems.»
Bibliography & references
  1. Monika Nowak,,Joanna Golec, Aneta Wieczorek, and  Piotr Golec. Is There a Correlation between Dental Occlusion, Postural Stability and Selected Gait Parameters in Adults? Int J Environ Res Public Health. 2023 Jan; 20(2): 1652. Published online 2023 Jan 16. doi: 10.3390/ijerph20021652. PMCID: PMC9862361. PMID: 36674407
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