Difference between revisions of "1° Clinical case: Hemimasticatory spasm"

 
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[[File:Spasmo emimasticatorio.jpg|left|300x300px]]
In the previous chapters we have considered the diagnostic complexity in medicine taking into account especially some parameters such as the hidden variables that only the evolution of basic knowledge over time will allow us to identify and the difficulties in decoding the encrypted signal that the Central Nervous System sends to the external in the form of verbal language.


Last but not least, the limitations imposed by a deterministic mindset that reduces knowledge in specialist contexts by limiting its diagnostic capacity. An alternative mindset to deterministics that primarily considers a logic of fuzzy language and the important contribution of quantum probability would allow us to expand the scientific-clinical horizons and delve into a mesoscopic reality.
'''Abstract''': This chapter, part of a series on medical diagnostics, focuses on the challenging diagnosis and treatment of "Hemimasticatory Spasm" in Mary Poppins. After enduring ten years of uncertainty and numerous tests across various disciplines, including dentistry and neurology, her case highlights the need for refined diagnostic approaches that integrate mathematical models and advanced neurophysiological understanding.


In this chapter, therefore, we will deal with the diagnosis of our Mary Poppins following the scientific-clinical process, evaluating the difficulties of implementation and the added value of the encrypted code identified in the hepaptic transmission.{{ArtBy|
The narrative emphasizes the limitations of conventional diagnostic frameworks, often hindered by deterministic thinking that fails to capture the nuances of human physiology. The chapter advocates for integrating quantum probability and fuzzy logic into medical diagnostics, proposing a shift toward a more probabilistic interpretation of patient symptoms and test results. This approach reflects the complex nature of many medical conditions and promotes more accurate and individualized patient care.
 
Mary Poppins' diagnosis was complicated by overlapping symptoms and the unclear boundary between dental and neurological issues. Traditional diagnostic methods fell short, leading to prolonged suffering. The introduction of the "ephaptic transmission" concept—a nuanced understanding of nerve communication—highlights the importance of sophisticated diagnostic tools and models to differentiate similar symptoms caused by different conditions.
 
The chapter critiques outdated medical paradigms that compartmentalize conditions into narrowly defined categories, often ignoring the broader systemic nature of many disorders. By invoking Thomas Kuhn's theory of scientific revolutions, the text challenges the medical community to reconsider existing models and adopt approaches that address human health complexities.
 
Moreover, the chapter discusses the role of "fuzzy logic" in diagnostics, allowing for a range of possibilities rather than binary outcomes. This is particularly relevant for neurological disorders, where symptoms can be transient or vary in intensity.
 
Mary Poppins' journey through the medical system, marked by misdiagnoses and partial treatments, exemplifies the consequences of inadequate diagnostic models. Her eventual correct diagnosis, facilitated by understanding "ephaptic transmission" within her trigeminal system, underscores the potential for improved outcomes with innovative, interdisciplinary approaches.
 
In conclusion, the chapter calls for a paradigm shift in medical diagnostics. It argues for moving away from mechanical interpretations of diseases like malocclusions to a holistic, system-oriented view incorporating neurophysiology and quantum mechanics. This shift promises better diagnostic accuracy and aligns more closely with the complex reality of human biology, potentially revolutionizing healthcare.
 
The chapter concludes by emphasizing continuous education and openness to new ideas among medical professionals, suggesting that integrating diverse scientific insights and emerging technologies into clinical practice is crucial for effective treatment.
 
{{ArtBy|
| autore = Gianni Frisardi
| autore = Gianni Frisardi
| autore2 = Giorgio Cruccu
| autore2 = Giorgio Cruccu
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| }}
| }}


=== Introduction ===
==Introduction==
From what has been exposed in the previous chapters from the 'Introduction' to the '[[Logic of medic language]]' chapters, beyond the complexity of the arguments and the vagueness of the verbal language, we found ourselves faced with a dilemma that of the context in which the patient is referred and in these cases for our poor Mary Poppins it seems to dominate the dental context, given the positive assertions reported by the clinical and laboratory tests performed on the patient.
From what has been exposed in the previous chapters from the 'Introduction' to the '[[Logic of medic language]]' chapters, beyond the complexity of the arguments and the vagueness of the verbal language, we found ourselves faced with a dilemma that of the context in which the patient is referred and in these cases for our poor Mary Poppins it seems to dominate the dental context, given the positive assertions reported by the clinical and laboratory tests performed on the patient.


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Basically, given the compatibility and consistency of sentence {{:F:Imo}} (dental context) with the assertions derived from the clinical test reporting {{:F:Delta series}}, consistently say that Orofacial Pain is caused by a Temporomandibular Disorder could become incompatible if another set of clinical statements <math>(\gamma_1,\gamma_2,.....\gamma_n \ )</math> were consistent with sentence <math>\Im_n</math> (neurological context) and contextually opposite, from a diagnostic point of view, to {{:F:Imo}}<blockquote>Therefore, there would be a source of logistical conflict between the two specialist contexts with inevitable diagnostic delay, also polluting the decryption process of the signal in the machine language of the Central Nervous System (CNS).</blockquote>What will determine the access key for decoding the encrypted code in machine language (SNC) and will allow us to intercept a demarcation line will be an irrefutable clinical and / or laboratory data called {{:F:Tau}}, which will confirm or exclude the consistency of an assertion than the other. It is essential, at this point, a <math>\Im_d</math> sentence (demarcation sentence) of the type will be:  <blockquote>Does Mary Poppins have a neuromotor disorder or a Temporomandibular Disorder? </blockquote>We explain this step in detail:
Basically, given the compatibility and consistency of sentence {{:F:Imo}} (dental context) with the assertions derived from the clinical test reporting {{:F:Delta series}}, consistently say that Orofacial Pain is caused by a Temporomandibular Disorder could become incompatible if another set of clinical statements <math>(\gamma_1,\gamma_2,.....\gamma_n \ )</math> were consistent with sentence <math>\Im_n</math> (neurological context) and contextually opposite, from a diagnostic point of view, to {{:F:Imo}}<blockquote>Therefore, there would be a source of logistical conflict between the two specialist contexts with inevitable diagnostic delay, also polluting the decryption process of the signal in the machine language of the Central Nervous System (CNS).</blockquote>What will determine the access key for decoding the encrypted code in machine language (SNC) and will allow us to intercept a demarcation line will be an irrefutable clinical and / or laboratory data called {{:F:Tau}}, which will confirm or exclude the consistency of an assertion than the other. It is essential, at this point, a <math>\Im_d</math> sentence (demarcation sentence) of the type will be:  <blockquote>Does Mary Poppins have a neuromotor disorder or a Temporomandibular Disorder? </blockquote>We explain this step in detail:


Si ricordi che da '[[The logic of classical language - en|The logic of classical language]]' si evince :  
Remember that da '[[The logic of classical language - en|The logic of classical language]]' this shows :  


*Un insieme di frasi {{:F:Im}}, e un numero <math>n\geq1</math> di altre asserzioni <math>(\delta_1,\delta_2,.....\delta_n \ )</math> sono logicamente compatibili se, e solo se, l'unione tra di loro <math>\Im\cup\{\delta_1,\delta_2.....\delta_n\}</math> è coerente
*A set of {{:F:Im}} sentences, and a <math>n\geq1</math> number of other <math>(\delta_1,\delta_2,.....\delta_n \ )</math> statements they are logically compatible if, and only if, the union between them <math>\Im\cup\{\delta_1,\delta_2.....\delta_n\}</math> it is consistent
*Un insieme di frasi {{:F:Im}}, e un numero  <math>n\geq1</math> di altre asserzioni <math>(\gamma_1,\gamma_2,.....\gamma_n \ )</math> sono logicamente incompatibili se, e solo se, l'unione tra di loro<math>\Im\cup\{\gamma_1,\gamma_2.....\gamma_n\}</math> è incoerente.
*A set of {{:F:Im}} sentences, and a <math>n\geq1</math> number of other <math>(\gamma_1,\gamma_2,.....\gamma_n \ )</math> statements they are logically incompatible if, and only if, the union between them <math>\Im\cup\{\gamma_1,\gamma_2.....\gamma_n\}</math> it is inconsistent


==== Significatività dei contesti ====
===Significance of the contexts===
Ora, per il '''contesto odontoiatrico''' avremo le seguenti frasi ed asserzioni a cui diamo un valore numerico per facilitare la trattazione e cioè <math>\delta_n=[0|1]</math> dove lo <math>\delta_n=0</math> indica 'normalità' e <math>\delta_n=1</math> 'anormalità e dunque positività del referto:


{{:F:Delta1}} Positive radiological report of the TMJ in Figure 2,  <math>\delta_1=1\longrightarrow</math> Anormalità, positività del referto
==== The '''dental context''' ====
Now, for the '''dental context''' we will have the following sentences and assertions to which we give a numerical value to facilitate the treatment and that is <math>\delta_n=[0|1]</math> where <math>\delta_n=0</math> indicates' normality' and <math>\delta_n=1</math> 'abnormality' and therefore positivity of the report:


{{:F:Delta2}} Positive CT report of the TMJ in Figure 3, <math>\delta_2=1\longrightarrow</math>Anormalità, positività del referto
{{:F:Delta1}} Positive radiological report of the TMJ in Figure 2, <math>\delta_1=1\longrightarrow</math> Abnormality, positivity of the report


{{:F:Delta3}} Positive axiographic report of the condylar traces in Figure 4, <math>\delta_3=1\longrightarrow</math> Anormalità, positività del referto
{{:F:Delta2}} Positive CT report of the TMJ in Figure 3,<math>\delta_2=1\longrightarrow</math> Abnormality, positivity of the report


{{:F:Delta4}} Asymmetric EMG interference pattern in Figure 5, .<math>\delta_4 =1\longrightarrow</math> Anormalità, positività del referto
{{:F:Delta3}} Positive axiographic report of the condylar traces in Figure 4, <math>\delta_3=1\longrightarrow</math> Abnormality, positivity of the report
 
{{:F:Delta4}} Asymmetric EMG interference pattern in Figure 5, <math>\delta_4 =1\longrightarrow</math> Abnormality, positivity of the report


<center>
<center>
<gallery widths="130" heights="200" perrow="5" slideshow""="" mode="slideshow">
<gallery widths="130" heights="200" perrow="5" slideshow""="" mode="slideshow">
File:Spasmo emimasticatorio ATM.jpg|'''Figure 2:'''  <math>\delta_1=</math> Stratigrafia dell'ATM del paziente che mostra segni di appiattimento condilare e osteofiti
File:Spasmo emimasticatorio ATM.jpg|'''Figure 2:'''  <math>\delta_1=</math> Patient TMJ stratigraphy showing signs of condylar flattening and osteophytes
File:Atm1 sclerodermia.jpg|'''Figure 3:''' <math>\delta_1=</math> Tomografia computerizzata dell'ATM che mostra l'appiattimento dell'ATM
File:Atm1 sclerodermia.jpg|'''Figure 3:''' <math>\delta_1=</math> Computed tomography of the TMJ showing flattening of the TMJ
File:1600px-Spasmo emimasticatorio assiografia.jpeg|''' Figure 4:''' <math>\delta_1=</math> Assiografia del paziente che mostra un appiattimento del pattern masticatorio sul condilo destro
File:1600px-Spasmo emimasticatorio assiografia.jpeg|''' Figure 4:''' <math>\delta_1=</math> Axiography of the patient showing a flattening of the chewing pattern on the right condyle
File:EMG2.jpg|'''Figure 5:''' <math>\delta_2=</math> Pattern interferenziale EMG. Tracce superiori sovrapposte corrispondenti al massetere destro, in basso al massetere sinistro.  
File:EMG2.jpg|'''Figure 5:''' <math>\delta_2=</math> EMG interference pattern. Overlapping upper traces corresponding to the right masseter, lower to the left masseter.
</gallery>
</gallery>
</center>
</center>          


La frase {{:F:Imo}} ( contesto odontoiatrico) con un numero <math>n\geq1</math> di altre asserzioni <math>(\delta_1,\delta_2,.....\delta_n \ )</math> logicamente compatibili determinano l'unione e la coerenza tra di loro <math>\Im_o\cup\{\delta_1,\delta_2.....\delta_n\}</math> e vengono rappresentate con un formalismo matematico per facilitare la dialettica diagnostica nel seguente modo:    
The sentence {{:F:Imo}} (dental context) with a number <math>n\geq1</math> of other logically compatible <math>(\delta_1,\delta_2,.....\delta_n \ )</math> assertions determine the union and coherence between them <math>\Im_o\cup\{\delta_1,\delta_2.....\delta_n\}</math> and are represented with a mathematical formalism to facilitate the diagnostic dialectic in the following way:          


<math>\Im_o\cup\{\delta_1,\delta_2.....\delta_n\}\rightarrow
<math>\Im_o\cup\{\delta_1,\delta_2.....\delta_n\}\rightarrow
\Im_o\cup\{1,1.....1\}=1</math> che rappresenta la media delle singole asserzioni refertate. La media è stata pensata perchè spesso può capitare che alcuni test diano risposte negative a cui dare il valore <math>\delta_n=0</math>
\Im_o\cup\{1,1.....1\}=1</math>  
 
 
which represents the average of the individual statements reported. The average was designed because it can often happen that some tests give negative answers to which to give the value <math>\delta_n=0</math>


Il risultato in questo caso è <math>\delta_n=1</math> e contestualmente ne deriva l'affermazione coerente della frase <math>\Im_o</math> in cui si sostiene che la sintomatologia della paziente Mary Poppins è determinata dalla presenza di una una DTMs.
The result in this case is <math>\delta_n=1</math> and at the same time it derives the coherent statement of the sentence <math>\Im_o</math> in which it is argued that the symptomatology of the patient Mary Poppins is determined by the presence of a DTMs.


{{Q2|Ma, paradossalmente, nel contesto neurologico
{{Q2|But, paradoxically, in the neurological context
<math>\Im_n </math> avremo lo stesso iter razionale:|ed è proprio qui che i contesti vanno in conflitto}}
<math>\Im_n </math> we will have the same rational process:|and it is precisely here that the contexts conflict}}


Nel '''contesto neurologico''' avremo, perciò, le seguenti frasi ed asserzioni a cui diamo un valore numerico per facilitare la trattazione e cioè <math>\gamma_n=[0|1]</math> dove lo <math>\gamma_n=0</math> indica 'normalità' e <math>\gamma_n=1</math> 'anormalità e dunque positività del referto:
==== The '''neurological context''' ====
In the '''neurological context''', therefore, we will have the following sentences and assertions to which we give a numerical value to facilitate the treatment and that is <math>\gamma_n=[0|1]</math> where <math>\gamma_n=0</math> indicates 'normality' and <math>\gamma_n=1</math> 'abnormality' and therefore positivity of the report:


<math>\gamma_1=</math> Assenza del jaw jerk in Figure 6,  <math>\gamma_1=1\longrightarrow</math> Anormalità, positività del referto


<math>\gamma_2=</math> Assenza del periodo silente masseterino in Figure 7, <math>\gamma_2=1\longrightarrow</math> Anormalità, positività del referto
<math>\gamma_1=</math> Absence of jaw jerk in Figures 6, <math>\gamma_1=1\longrightarrow</math> Abnormality, positivity of the report


<math>\gamma_1=</math> Ipertrofia del massetere destro alla TC in Figure 8, <math>\gamma_3=1\longrightarrow</math> Anormalità, positività del referto
<math>\gamma_2=</math> Absence of the silent masseterine period in Figures 7, <math>\gamma_2=1\longrightarrow</math> Abnormality, positivity of the report
 
<math>\gamma_1=</math> Hypertrophy of the right masseter on CT in Figures 8, <math>\gamma_3=1\longrightarrow</math> Abnormality, positivity of the report


<center>
<center>
<gallery widths="250" heights="200" perrow="3" slideshow""="" mode="slideshow">
<gallery widths="250" heights="200" perrow="3" slideshow""="" mode="slideshow">
File:Spasmo emimasticatorio JJ.jpg|'''Figure 6:''' <math>{\gamma _{1}}=</math> Jaw jerk rilevato elettrofisiologicamente sui masseteri destro (tracce superiori) e sinistro (tracce inferiori)
File:Spasmo emimasticatorio JJ.jpg|'''Figure 6:''' <math>{\gamma _{1}}=</math> Jaw jerk detected electrophysiologically on the right (upper traces) and left (lower traces) masseters
File:Spasmo emimasticatorio SP.jpg|'''Figure 7:''' <math>\gamma _2=</math> Periodo silente meccanico rilevato elettrofisiologicamente sui masseteri di destra (tracce sovrapposte superiori) e di sinistra (tracce sovrapposte inferiori)
File:Spasmo emimasticatorio SP.jpg|'''Figure 7:''' <math>\gamma _2=</math> Mechanical silent period detected electrophysiologically on the right (upper overlapping traces) and left (lower overlapping traces) masseters
File:Spasmo emimasticatorio TC.jpg|''' Figure 8:''' <math>\gamma _3=</math> La TC mostra un'evidente ipertrofia del massetere destro
File:Spasmo emimasticatorio TC.jpg|''' Figure 8:''' <math>\gamma _3=</math> CT shows evident hypertrophy of the right masseter
</gallery>
</gallery>
</center>
</center>


Ora di conseguenza anche a frase <math>\Im_n</math> con un numero <math>n\geq1</math> di altre asserzioni <math>(\gamma_1,\gamma_2,.....\gamma_n \ )</math> logicamente compatibili determinano l'unione e coerenza tra di loro <math>\Im_n\cup\{\gamma_1,\gamma_2.....\gamma_n\}</math> e la rappresentazione formale ssarà simile a quella del contesto odontoiatrico:
Now consequently also sentence <math>\Im_n</math> with a number <math>n\geq1</math> of other logically compatible statements <math>(\gamma_1,\gamma_2,.....\gamma_n \ )</math> determine the union and coherence between them <math>\Im_n\cup\{\gamma_1,\gamma_2.....\gamma_n\}</math> and the formal representation will be similar to that of the dental context:




<math>\Im_n\cup\{\gamma_1,\gamma_2.....\gamma_n\}\rightarrow
<math>\Im_n\cup\{\gamma_1,\gamma_2.....\gamma_n\}\rightarrow
\Im_n\cup\{1,1.....1\}=1</math> con contestuale affermazione coerente della frase <math>\Im_n</math> in cui si sostiene che la sintomatologia della paziente Mary Poppins ha un causa neuromotorio e le conseguenze cliniche di tipo occlusali masticatorie non sono altro che una conseguenza del danno neuropatico.  
\Im_n\cup\{1,1.....1\}=1</math> with contextual coherent affirmation of sentence <math>\Im_n</math> in which it is argued that the symptomatology of the patient Mary Poppins has a neuromotor cause and the clinical consequences of a masticatory occlusal type are nothing other than a consequence of the neuropathic damage.


{{Q2|In questo scenario ambedue le affermazioni <math>\Im_o </math> e <math>\Im_n </math> sono compatibili, coerenti e dunque vere fino a che non si trova un 'Demarcatore di coerenza' che abbiamo chiamato precedentemente 'τ'
{{Q2|In this scenario both the statements <math>\Im_o </math> and <math>\Im_n </math> are compatible, consistent and therefore true until a 'demarcator of coherence' is found which we previously called <math>\tau</math>
.}}
}}


==== Demarcatore di Coerenza <math>\tau</math>====
=== Demarcator of coherence <math>\tau</math>===
Il <math>\tau</math> è un rappresentativo peso specifico clinico, complesso da ricercare e mettere a punto perchè varia da disciplina a disciplina e per patologie, essenziale per non far collidere le asserzioni logiche  <math>\Im_o</math> e <math>\Im_n</math> nelle procedure diagnostiche e fondamentale per inizializzare la decriptazione del codice di comunicazione logica. Sostanzialmente permette di confermare la coerenza di una unione <math>\Im\cup\{\delta_1,\delta_2.....\delta_n\}</math> rispetto ad una altra <math>\Im\cup\{\gamma_1,\gamma_2.....\gamma_n\}</math> e viceversa, dando un peso maggiore alla gravità delle asserzioni e del referto nel contesto appropriato.  
The <math>\tau</math> is a representative clinical specific weight, complex to research and fine-tune because it varies from discipline to discipline and for pathologies, essential in order not to make logical assertions collide <math>\Im_o</math> and <math>\Im_n</math> in the diagnostic procedures and essential to initialize the decryption of the logic communication code. Basically it allows you to confirm the consistency of a union <math>\Im\cup\{\delta_1,\delta_2.....\delta_n\}</math> with respect to another <math>\Im\cup\{\gamma_1,\gamma_2.....\gamma_n\}</math> and vice versa, giving greater weight to the severity of the statements and the report in the appropriate context.


A volte il medico si trova di fronte ad una serie di refertazioni positive a cui dare il giusto peso, deve considerare la positività di un referto che evidenzia, per esempio,  un rimodernamento osteoarticolare della ATM non può avere lo stesso peso di una positività di un referto che conferma un ritardo di latenza di un riflesso trigeminale.  
Sometimes the physician is faced with a series of positive reports to which to give due weight, he must consider the positivity of a report that highlights, for example, an osteoarticular remodeling of the TMJ cannot have the same weight as a positivity of a report confirming a latency delay of a trigeminal reflex.  


Il peso di demarcazione <math>\tau</math>, perciò, dà più significatività alle asserzioni più gravi nel contesto clinico da cui derivano e dunque al di là della positività delle asserzioni <math>\delta_n=1</math> oppure <math>\gamma_n=1</math> che comunque sono sempre verificate e rispettate, queste dovranno essere moltiplicate per un <math>\tau=[0|1]</math> dove lo <math>\tau=0</math> indica 'Gravità bassa' mentre <math>\tau=1</math> 'Gravità severa' .
The weight of demarcation <math>\tau</math>, therefore, gives more significance to the most serious assertions in the clinical context from which they derive and therefore beyond the positivity of the <math>\delta_n=1</math> or <math>\gamma_n=1</math> assertions which in any case are always verified and respected, these must be multiplied by a <math>\tau=[0|1]</math> where <math>\tau=0</math> indicates 'Low severity' while <math>\tau=1</math> 'High severity'.


Nel contesto neurologico il <math>\tau</math> riguarda la presenza di ritardi e/o assenza in latenza del jaw jerk, durata e/o assenza del periodo silente masseterino oltre altri parametri che per il momento non è necessario descrivere. Un ritardo superiore al valore normativo oppure una assenza dei test sopracitati viene considerato come peso specifico grave ed assoluto corrispondente ad una valenza dominante rispetto all'altro contesto clinico.
In the neurological context, <math>\tau</math> concerns the presence of delays and/or latency absence of the jaw jerk, duration and/or absence of the masseterine silent period as well as other parameters that for the moment it is not necessary to describe. A delay greater than the normative value or an absence of the aforementioned tests is considered as a serious and absolute specific weight corresponding to a dominant valence with respect to the other clinical context.  


Per ricapitolare abbiamo dunque:
To recap we therefore have:
----


 
<math>\Im_o\cup \{({\bar\delta_n)} \tau_o + \Im_n\cup\{({\bar\gamma_n)}\  
 
<math>\Im_o\cup \{( \bar{\delta_n)} \tau_o + \Im_n\cup\{( \bar{\gamma_n)}\  
\tau_n=
\tau_n=
\Im_d
\Im_d
</math>  
</math>  


dove
where
 
<math>\bar{\delta_n}=</math> media del valore delle asserzioni cliniche nel contesto odontoiatrico e dunque <math>\bar{\delta_n}=1</math>


<math>\bar{\gamma_n}=</math> media del valore delle asserzioni cliniche nel contesto neurologico e dunque <math>\bar{\gamma_n}=1</math>
<math>{\bar\delta_n}=</math> average of the value of clinical statements in the dental context and therefore <math>{\bar\delta_n}=1</math>


<math>\tau_o=0</math> refertazione di bassa gravità del contesto odontoiatrico
<math>{\bar\gamma_n}=</math> average of the value of clinical statements in the neurological context and therefore<math>{\bar\gamma_n}=1</math>


<math>\tau_n=1</math> refertazione di alta gravità del contesto neurologico
<math>\tau_o=0</math> low severity performance of the dental context<math>\tau_n=1</math>reporting of high severity of the neurological context


in cui il 'demarcatore di coerenza <math>\tau</math>' definirà il percorso diagnostico nel seguente modo
where the 'coherence marker '<math>\tau</math>' will define the diagnostic path as follows




Line 123: Line 137:
</math>
</math>


{{Q2|Questa procedura di sintassi logica formale ci ha permesso di eliminare le interferenze della asserzioni a bassa gravità clinica e definire rapidamente un percorso diagnostico neurologico piuttosto che odontoiatrico attraverso la definizione di <math>\Im_d= \Im_n
{{Q2|This formal logic syntax procedure allowed us to eliminate the interference of low clinical severity assertions and quickly define a neurological rather than dental diagnostic path through the definition of  <math>\Im_d= \Im_n
</math> }}
</math> }}


Una volta lavata via la miriade di dati normativi refertati positivamente, che generano conflittualità tra contesti, grazie al demarcatore di coerenza <math>\tau</math> abbiamo un quadro molto più chiaro e lineare su cui approfondire l'analisi della funzionalità del Sistema Nervoso Centrale. Di conseguenza possiamo concentrarsi nell'intercettare i tests necessari per decriptare il codice del linguaggio macchina che il SNC invia all'esterno convertito in linguaggio verbale.
Once we have washed away the myriad of positively reported normative data, which generate conflicts between contexts, thanks to the coherence marker <math>\tau</math> we have a much clearer and more linear picture on which to deepen the analysis of the functionality of the Central Nervous System. Consequently we can concentrate on intercepting the tests necessary to decrypt the machine language code that the SNC sends out converted into verbal language.
 
==Ephaptic transmission==
With a little effort and patience on the part of passionate readers who have followed the entire logical path, sometimes apparently off topic, we have reached a clinical picture in which the code to be decrypted is inherent in neuromotor damage. Consequently, the access keys to the code, the one that figuratively corresponds to the exact decryption algorithm, would correspond to the right choice of the neuromotor damage detector test. 
 
This is a point where it is essential to infer the clinician's intuition because finding the right algorithm to decrypt the code, after the aforementioned filter steps that have been described to wash away the interference of assertions, means at least choosing the right dictionary, for example, that of the image (MR of the brain rather than the neck); acoustic and vestibular evoked potentials (if a vestibular scwannoma is suspected) or trigeminal electrophysiological study (if more than one trigeminal involvement is suspected).
 
In this clinical iter that we have presented, the choice of the clinician to follow the electrophysiological trigeminal roadmap from which the positivity of the <math>\bar{\gamma_n}=1</math> assertions have already been derived, therefore, having already defined a picture of serious anomaly of absence of the jaw jerk and of the silent period masseterino on the right side of the patient will have to understand if the damage is intracranial or extracranial.
 
To do this, the clinician uses an electrical stimulation test of the masseter nerve in infratemporal fossa called <math>M-wave</math> on the masseter muscle with simultaneous recording of the heteronymous <math>H-wave</math> on the temporal muscle<ref>{{cita libro
| autore = Cruccu G
| autore2 = Truini A
| autore3 = Priori A
| titolo = Excitability of the human trigeminal motoneuronal pool and interactions with other brainstem reflex pathways
| url = https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2278464/pdf/tjp0531-0559.pdf
| volume =
| opera = J Physiol
| anno = 2001
| editore = The Physiological Society
| città =
| ISBN =
| DOI = 10.1111/j.1469-7793.2001.0559i.x
| PMID = 11230527
| PMCID = PMC2278464
| oaf = <!-- qualsiasi valore -->
| LCCN =
| OCLC =
}}</ref> and a bilateral transcranial electrical stimulation of the trigeminal motor roots called, precisely, <math>_bRoot-MEPs</math><ref name="fris1992">{{cita libro
| autore = Frisardi G
| titolo = The use of transcranial stimulation in the fabrication of an occlusal splint
| url = https://www.sciencedirect.com/science/article/abs/pii/002239139290345B
| volume =
| opera = J Prosthet Dent
| anno = 1992
| editore = Mosby, Inc - Elsevier
| città =
| ISBN =
| DOI = 10.1016/0022-3913(92)90345-b
| PMID = 1501190
| PMCID =
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===M-wave===
The right masseter nerve was electrically stimulated in the infratemporal fossa (see clinical procedure chapter: [[Encrypted code: Ephaptic transmission]]) with a technique similar to that described by Macaluso & De Laat (1995).<ref>Macaluso G, De Laat A. [https://pubmed.ncbi.nlm.nih.gov/8773249/ H-reflexes in masseter and temporalis muscle in man. Experimental] Brain Research. 1995;107:315–320. [PubMed] [Google Scholar] [Ref list]</ref> Square cathode pulses (0.1 ms) generated by an electrical stimulator (Neuropack X1, Nihon Kohden Corporation, Tokyo, Japan) were delivered through a Teflon-coated monopolar needle electrode (TECA 902-DMG25, 53534) with a tip non-isolated (diameter 0.36 mm; area 0.28 mm2) inserted 1.5 cm through the skin below the zygomatic arch and anterior to the temporomandibular joint in the infratemporal fossa with electrical shocks of 0.5 - 5 mA, and 0.1 ms. The anode was a surface non-polarizable Ag-AgCl disc electrode (OD 9.0 mm) positioned over the ipsilateral ear lobe. Electrical stimulation of the masseter nerve never produced pain, and the subjects only perceived muscle contraction. The correct position of the stimulation electrodes was monitored throughout the experimental session by checking online the size of the M wave in the masseter muscle. The signals were recorded by placing surface electrodes on the masseter and temporal muscles and filtered at 10-2000Hz and by concentric needle electrodes inserted into the anterior temporal muscle.


=== Trasmissione efaptica ===
{{Q2|The response in the right masseter was clearly delayed but relatively symmetrical in amplitude between sides. (Fig. 9)}}
Si è giunto, con un pò di fatica e pazienza da parte dei lettori appassionati che hanno seguito l'intero percorso logico a volte apparentemente fuori tema, ad un quadro clinico in cui il codice da decriptare è insito nel danno neuromotorio. Di conseguenza le chiavi di accesso al codice, quello che figurativamente corrisponderebbe all'algoritmo esatto di decriptazione, corrisponderebbe alla giusta scelta del test rilevatore del danno neuromotorio.


Questo è un punto in cui è indispensabile arguire l'intuito del clinico perchè trovare l'algoritmo giusto per decriptare il codice, dopo i citati passaggi di filtro che sono stati descritti per lavare via le interferenze di asserzioni, significa almeno scegliere il dizionario giusto, per esempio, quello dell'immagine ( MR dell'encefalo piuttosto che del collo); potenziali evocati acustici e vestibolari ( nel caso si sospetti di uno scwannoma vestibolare) oppure lo studio elettrofisiologico trigeminale ( nel caso si sospetti più un coinvolgimento trigeminale).  
===<sub>b</sub>Root-MEPs===
The trigeminal root was stimulated transcrally through high voltage, low impedance through an electrical stimulator (Neuropack X1, Nihon Kohden Corporation, Tokyo, Japan)) with the anode electrode positioned at the apex and the cathode approximately 10 cm laterally from the apex along a line vertex acoustic meatus. The electric field is believed to excite the trigeminal motor nerve fibers via the trancranial route, near their exit from the skull.<ref name="fris1992" /><ref>G Frisardi, P Ravazzani, G Tognola, F Grandori. [https://pubmed.ncbi.nlm.nih.gov/9467995/ Electric versus magnetic transcranial stimulation of the trigeminal system in healthy subjects. Clinical applications in gnathology.] J Oral Rehab.1997 Dec;24(12):920-8.doi: 10.1046/j.1365-2842.1997.00577.x.</ref> Also in this case, the response in the right masseter was markedly delayed (3.5 ms on the right side 2 ms on the left and dispersed. amplitude of the M-wave.


Viene da se, in questo iter clinico che abbiamo presentato, la scelta del clinico di seguire la roadmap elettrofisiologica trigeminale da cui già sono derivate le positività delle asserzioni <math>\bar{\gamma_n}=1</math>, per cui, avendo già definito un quadro di anomalia grave di assenza del jaw jerk e del periodo silente masseterino sul lato destro della pazientesi dovrà capire se il danno sia intracranico oppure extracranico. 


Per fare ciò il clinico impiega un  test di stimolazione elettrica del nervo masseterino in fossa infratemporale chiamato <math>M-wave</math> sul muscolo massetere con contestuale registrazione della heteronymous <math>H-wave</math> sul muscolo temporale<ref>https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2278464/#__ffn_sectitle</ref> ed una stimolazione transcraniale elettrica bilaterale delle radici motorie trigeminali chiamato, appunto, <math>_bRoot-MEPs</math><ref name=":2">G '''Frisardi.''' [https://www.sciencedirect.com/science/article/pii/002239139290345B The use of transcranial stimulation in the fabrication of an occlusal splint]. The Journal of prosthetic dentistry, 1992 - Elsevier</ref> 
[[File:TCS Lupo edited.jpg|center|thumb|600x600px|'''Figure 9:''' The responses evoked by stimulation of the masseter nerve M-wave and the trigeminal Root-MEPs are clearly delayed on the right side while maintaining the amplitude relatively symmetrical.]]


====M-wave ====
Il nervo masseterico destro è stato stimolato elettricamente nella fossa infratemporale (vedi procedura clinica capitolo: [[Encrypted code: Ephaptic transmission]] ) con una tecnica simile a quella descritta da Macaluso & De Laat (1995)<ref>Macaluso G, De Laat A. [https://pubmed.ncbi.nlm.nih.gov/8773249/ H-reflexes in masseter and temporalis muscle in man. Experimental] Brain Research. 1995;107:315–320. [PubMed] [Google Scholar] [Ref list]</ref>. Gli impulsi quadrati catodici (0,1 ms) generati da uno stimolatore elettrico  (Neuropack X1, Nihon Kohden Corporation, Tokyo, Japan) sono stati erogati attraverso un elettrodo ad ago monopolare rivestito di teflon (TECA 902-DMG25, 53534) con una punta non isolata (diametro 0,36 mm; area 0,28 mm2) inserito a 1,5 cm attraverso la pelle al di sotto dell'arco zigomatico e anteriormente all'articolazione temporo-mandibolare nella fossa infratemporale con shock elettrici di 0,5 -5  mA, e 0,1 ms. L'anodo era un elettrodo a disco Ag-AgCl non polarizzabile di superficie (diametro esterno 9,0 mm) posizionato sopra il lobo omolaterale dell'orecchio. La stimolazione elettrica del nervo masseterico non ha mai prodotto dolore e i soggetti hanno percepito solo la contrazione muscolare. La corretta posizione degli elettrodi di stimolazione è stata monitorata durante tutta la sessione sperimentale controllando on-line la dimensione dell'onda M nel muscolo massetere. I segnali furono registrati attraverso posizionamento sui muscoli masseteri e temporali di elettrodi di superficie e filtrati a 10-2000Hz e da elettrodi concentrici ad ago inseriti nel muscolo temporale anteriore.


{{Q2|La risposta nel massetere destro fu chiaramente ritardata ma relativamente simmetrica in ampiezza tra lati.( fig 9)}}
Having highlighted, through the execution of the <math>M-wave</math> and <math>_bRoot-MEPs</math> test, a delay in the conduction speed of the trigeminal nerve fibers generates the suspicion that it is a focal demyelination. This indicates that the problem is to be referred to the nervous component rather than to the muscular one, therefore, our attention should focus on the type of focal demyelination, extent of damage and presumably localization of the damage. The differential diagnosis at this point focuses on the type and area of the demyelinating damage, for example, if it is a damage exclusively referred to the masseterine motor nerve or the motor nerve of the temporal muscle is also involved, important for treatment with botulinum endotoxin. To resolve this doubt it is necessary to evoke a heteronymous <math>H-wave</math> response from recording on the temporal muscle.


====<sub>b</sub>Root-MEPs====
===H-wave===
La radice trigeminale fu stimolata transcralmente attraverso alta tensione, bassa impedenza attraverso uno stimolatore elettrico ( Neuropack X1, Nihon Kohden Corporation, Tokyo, Japan)) con l'elettrodo anodico posizionato al vertice ed il catodico a circa 10 cm lateralmente dal vertice lungo una linea vertice meato acustico. Si ritiene che il campo elettrico ecciti le fibre nervose motorie del trigemino per via trancranica, vicino alla loro uscita dal cranio.<ref name=":2" /><ref>G Frisardi, P Ravazzani, G Tognola, F Grandori. [https://pubmed.ncbi.nlm.nih.gov/9467995/ Electric versus magnetic transcranial stimulation of the trigeminal system in healthy subjects. Clinical applications in gnathology.] J Oral Rehab.1997 Dec;24(12):920-8.doi: 10.1046/j.1365-2842.1997.00577.x.</ref> Anche in questo caso, la risposta nel massetere destro fu marcatamente ritardata ( 3,5 ms sul lato destro 2 ms sul sinistro e dispersa. (fig.9)  concludendo che si è di fronte ad una marcato ritardo della conduzione nervosa senza una riduzione in ampiezza della M-wave.
The arrangement is similar to that previously described with regard to the <math>M-wave</math> with the variant that the temporal muscle is recorded simultaneously with the stimulation of the masseterine nerve in the intratemporal fossa by a bipolar needle electrode. The stimulation must be gradually adapted in order to evoke both a <math>M-wave</math> from the masseter that a heteronymous <math>H-wave</math> from the temporal muscle.
[[File:TCS Lupo edited.jpg|center|thumb|600x600px|'''Figura 9:''' Le risposte evocate da stimolazione del nervo masseterino M-wave e della radice trigeminale Root-MEPs sono chiaramente ritardate sul lato destro pur mantenendo relativamente simmetrica l'ampiezza]]


In our patient Mary Poppins, unfortunately, the neuromotor situation is quite complex and serious because to the infratemporal stimulation of the masseteral nerve we have a direct evoked response on the muscle ipsilateral to the stimulation (figure 10; <math>M-wave</math>) and at the same time not a heteronymous response (figure 10; <math>H-wave</math> ) on the temporal muscle but rather a tonic asynchronous activity (Figure <math>E</math>)


L'aver evidenziato, attraverso l'esecuzione del test della <math>M-wave</math> e della <math>_bRoot-MEPs</math>, un ritardo di velocità di conduzione delle fibre nervose trigeminale genera il sospetto che si tratti di una demielinizzazione focale. Questo sta ad indicare che il problema è da riferire alla componente nervosa più che a quella muscolare per cui, la nostra attenzione dovrebbe convergere sul tipo di demielinizzazione focale, entità del danno e presumibilmente localizzazione del danno. La diagnosi differenziale a questo punto verte sul tipo e zona del danno demielinizzante per esempio, se si tratta di un danno esclusivamente riferito al nervo motorio masseterino oppure sia coinvolto anche il nervo motorio del muscolo temporale, importante per il trattamento con endotossina botulinica. Per risolvere questo dubbio è necessario evocare una risposta heteronymous  <math>H-wave</math> da registrazione sul muscolo temporale.
This neurophysiopathological phenomenon is called 'Ephaptic transmission' and allows us to confirm the presence of demyelinating lesions also of the motor nerve of the temporal muscle.


====H-wave ====
As previously mentioned and in order not to burden the topic, the detailed description of the 'Hephaptic' phenomenon will be treated in the chapter '[[Encrypted code: Ephaptic transmission]]' in order to better understand the physiological responses of heteronymous <math>H-wave</math> by pathological ones.
La disposizione è simile a quanto descritto precedentemente riguardo alla <math>M-wave</math> con la variante che viene registrato simultaneamente alla stimolazione del nervo masseterino in fossa intratemporale anche il muscolo temporale con un elettrodo ad ago bipolare. La stimolazione deve essere gradualmente adattata per poter evocare sia una <math>M-wave</math> dal massetere che una heteronymous <math>H-wave</math> dal muscolo temporale.


Nella nostra paziente Mary Poppins, purtroppo, la situazione neuoromotoria è alquanto complessa e grave perchè alla stimolazione infratemporale del nervo masseterino abbiamo una risposta evocata diretta sul muscolo ipsilaterale alla stimolazione  ( figura 10; <math>M-wave</math>) e contestualmente non una risposta  heteronymous (figura 10; <math>H-wave</math> ) sul muscolo temporale bensì una attività asincrona tonica ( figura 10; <math>E</math> )


Questo fenomeno neurofisiopatologico viene denominato ''''Trasmissione efaptica'''<nowiki/>' e ci permette di confermare la presenza di lesioni demielinizzanti anche del nervo motorio del muscolo temporale.
[[File:Hephaptic edited.jpeg|center|thumb|600x600px|'''Figure 10:''' On the left side indicated with EMG the recording of the motor unit discharge on the right masseter at the time of the spasm is shown while on the right below indicated with M-wave we can see two motor potentials evoked by the electrical stimulation in infratemporal fossa recorded on the masseter. With H-wave it is possible to note the recording of the heteronomous H-wave on the temporal ipsilateral to the stimulation.]]


Come citato precedentemente e per non appesantire l'argomento la descrizione dettagliata del fenomeno 'Efaptico' verrà trattato nel capitolo '[[Encrypted code: Ephaptic transmission]]' in modo si possano comprendere meglio le risposte fisiologiche della heteronymous <math>H-wave</math> da quelle patologiche.
=== Conclusions===


Following this step by step path we have demonstrated a peripheral motor nerve injury as originally proposed by Kaufman.<ref name="kauf">Kaufman MD. [https://pubmed.ncbi.nlm.nih.gov/7436363/ Masticatory spasm in facial hemiatrophy]. Ann Neurol 1980;7:585-7.</ref> Conduction studies have shown a slowing of conduction in the extracranial course of masticatory nerve fibers without a reduction in the amplitude of <math>M-wave</math> and obviously EMG signs of chronic denervation. The temporal muscle biopsy appeared histologically normal.


[[File:Hephaptic edited.jpeg|center|thumb|600x600px|'''Figura 10:''' A destra indicato con EMG viene mostrata la registrazione della scarica di unità motorie sul massetere destro al momento dello spasmo mentre a destra in basso indicato con M-wave possiamo notare due potenziali motori evocati dalla stimolazione elettrica in fossa infratemporale registrata sul massetere. Con H-wave si può notare la registrazione della eteronoma H-wave sul temporale ipsilaterale alla stimolazione.]]
{{Q2|These results indicate axon-sparing demielination.}}


=== Conclusioni ===
The absence of the jaw jerk on the diseased side indicates damage to the large diameter afferent fibers ({{:F:A-alpha}}) from the neuromuscular spindles. A lesion of few afferents {{:F:A-alpha}} could easily abolish the jaw jerk.<ref>Cruccu G, Inghilleri M, Fraioli B, Guidetti B, et al. [https://pubmed.ncbi.nlm.nih.gov/3561775/ Neurophysiologic assessment of trigeminal function after surgery for trigeminal neuralgia]. Neurology 1987; 37:631-8.</ref>


Seguendo questo percorso step by step abbiamo dimostrato una lesione del nervo periferico motorio come originariamente proposto da Kaufman.<ref name=":0">Kaufman MD. [https://pubmed.ncbi.nlm.nih.gov/7436363/ Masticatory spasm in facial hemiatrophy]. Ann Neurol 1980;7:585-7.</ref> Studi sulla conduzione hanno mostrato un rallentamento di conduzione nel decorso extracranico delle fibre nervose masticatorie senza una riduzione di ampiezza della <math>M-wave</math> ed ovviamente segni EMG di denervazione cronica. La biopsia dei muscoli temporali apparivano istologicamente normali.
Muscle nerve damage would not be explained only because patients with Hemimasticatory Spasm (HMS) do not have sensory disturbances but also because they often only have spasms in one or two levator mandibular muscles. These observations argue against damage to the motor root or to the intracranial portion of the mandibular nerve where the motor bundles are closely grouped,<ref>Pennisi E, Cruccu G, Manfredi M, Palladini G. [https://pubmed.ncbi.nlm.nih.gov/1795166/ Histometric study of myelinated fibers in the human trigeminal nerve]. J Neurol Sci 1991;105:22-8.</ref> favoring damage to the individual muscle nerves that pass through the infratemporal fossa.


{{Q2|Questi risultati indicano una demielinazione con risparmio dell'assone. }}
The mechanism of involvement of facial paroxysmal involuntary activity has been discussed by Kaufnan<ref name="kauf" /> and by Thompson and Carroll<ref>Thompson PD, Carroll WM. [https://pubmed.ncbi.nlm.nih.gov/6842234/ Hemimasticatory spasm: a peripheral paroxysmal cranial neuropathy?] J Neurol NeurosurgPsychiatry 1983;46:274-6.</ref> who emphasized the close similarity between hemimasticatory and hemifacial spasm.


L'assenza del jaw jerk sul lato malato indica un danno delle fibre afferenti di grande diametro ({{:F:A-alpha}}) dai fusi neuromuscolari.  Una lesione di poche afferenze {{:F:A-alpha}} potrebbero facilmente abolire il jaw jerk.<ref>Cruccu G, Inghilleri M, Fraioli B, Guidetti B, et al. [https://pubmed.ncbi.nlm.nih.gov/3561775/ Neurophysiologic assessment of trigeminal function after surgery for trigeminal neuralgia]. Neurology 1987; 37:631-8.</ref>
In EMG, these prolonged spasms fit perfectly into the description of cramps, that is, discharges of irregular motor units that progressively increase, leading to the recruitment of much of the muscle of synchronous discharges at speeds of 40 to 60 Hz.<ref>Kimura J. Electrodiagnosis in diseases of nerve and muscle: principles and practice, 2nd edn. Philadelphia: FA Davis 1989.</ref> Common to hemifacial spasm and cramps however, ectopic EMG activities can also be detected.


Il danno nervoso muscolare non si spiegherebbe solo perché i pazienti con Spasmo Emimasticatorio (HMS) non hanno disturbi sensoriali ma anche perché spesso hanno solo spasmi in uno o due muscoli elevatori mandibolare. Questi osservanzioni argomentano contro i danni alla  radice motoria oppure alla porzione intracranica del nervo mandibolare dove i fasci motori sono strettamente raggruppati<ref>Pennisi E, Cruccu G, Manfredi M, Palladini G. [https://pubmed.ncbi.nlm.nih.gov/1795166/ Histometric study of myelinated fibers in the human trigeminal nerve]. J Neurol Sci 1991;105:22-8.</ref> favorendo un danno dei singoli nervi muscolari che passano attraverso la fossa infratemporale.
This could be responsible for the high frequency of EMG discharges at a frequency of 100-200 Hz and the synchronization of the entire muscle or multiple muscles, and post-activity. The synchronization could be explained by the lateral spread of discharges from adjacent nerve fibers,<ref>Nielsen VK. [https://pubmed.ncbi.nlm.nih.gov/6322049/ Pathophysiology of hemifacial spasm: II. Lateral spread of the supraorbital nerve reflex]. Neurology 1984;34:427-31.</ref><ref>Thompson PD. Stiff people. In Fahn S, Marsden CD, eds. Movement disorders 3. London: Butterworths, 1993: 367-99.</ref> generating a local re-excitation circuit. Posthumous EMG activity consists of paroxysmal discharges that may follow a voluntary orthodromic contraction or antidromic impulses,<ref>Auger RG. [https://pubmed.ncbi.nlm.nih.gov/573406/ Hemnifacial spasm: clinical and electrophysio- logic observations.] Neurology 1979;29: 1261-72.</ref><ref name="niels">Nielsen VK. [https://pubmed.ncbi.nlm.nih.gov/6322048/ Pathophysiology of hemifacial spasm: I. Ephaptic transmission and ectopic excitation.] Neurology 1984;34:418-26.</ref> and is attributed to self-excitation of the same axons after the passage of an impulse.


Il meccanismo di coinvolgimento dell'attività involontaria parossistica facciale è stata discussa da Kaufnan<ref name=":0" /> e da Thompson e Carroll<ref>Thompson PD, Carroll WM. [https://pubmed.ncbi.nlm.nih.gov/6842234/ Hemimasticatory spasm: a peripheral paroxysmal cranial neuropathy?] J Neurol NeurosurgPsychiatry 1983;46:274-6.</ref> che hanno sottolineato la stretta somiglianza tra spasmo emimasticatorio ed emifacciale. 


Nell'EMG, questi spasmi prolungati si adattano perfettamente alla descrizione di crampi, cioè scariche  di unità motoria irregolare che progressivamente aumentano, portando al reclutamento di gran parte del muscolo di scariche sincrone a velocità da  40 a 60 Hz.<ref>Kimura J. Electrodiagnosis in diseases of nerve and muscle: principles and practice, 2nd edn. Philadelphia: FA Davis 1989.</ref> Comune allo spasmo emifacciale e i crampi, tuttavia, si possono rilevare anche attività EMG  ectopiche.


Questo potrebbe essere responsabile dell'alta frequenza di scariche EMG a frequenza di 100-200 Hz e della sincronizzazione dell'intero muscolo o di più muscoli, e post-attività. La sincronizzazione potrebbe essere spiegata dalla diffusione laterale di scariche delle fibre nervose adiacenti,<ref>Nielsen VK. [https://pubmed.ncbi.nlm.nih.gov/6322049/ Pathophysiology of hemifacial spasm: II. Lateral spread of the supraorbital nerve reflex]. Neurology 1984;34:427-31.</ref><ref>Thompson PD. Stiff people. In Fahn S, Marsden CD, eds. Movement disorders 3. London: Butterworths, 1993: 367-99.</ref> generando un circuito locale di re-eccitazione. Attività EMG postuma consiste di scariche parossistiche che possono seguire una contrazione ortodromica volontaria o impulsi antidromici, <ref>Auger RG. [https://pubmed.ncbi.nlm.nih.gov/573406/ Hemnifacial spasm: clinical and electrophysio- logic observations.] Neurology 1979;29: 1261-72.</ref><ref name=":1">Nielsen VK. [https://pubmed.ncbi.nlm.nih.gov/6322048/ Pathophysiology of hemifacial spasm: I. Ephaptic transmission and ectopic excitation.] Neurology 1984;34:418-26.</ref> ed è attribuito ad auto-eccitazione degli stessi assoni dopo il passaggio di un impulso.
In our patient Mary Poppins we observed a synchronization of the whole or a large part of the muscle involved in the spasm (fig 10, EMG); the self-excitation is evidenced by the recording of the evoked discharges following the response of the stimulation of the chewing nerves (Fig. 10, E). These results support the hypothesis that spontaneous activity 'arises' in a demyelinated peripheral nerve, a phenomenon called hepaptic.<ref name="niels" />


Nella nostra paziente Mary Poppins abbiamo osservato una sincronizzazione dell'intero o di una gran parte del muscolo coinvolto dallo spasmo (fig 10, EMG); l'auto-eccitazione si evidenzia dalla registrazione delle scariche evocato successive alla risposta della stimolazione dei nervi masticatori (fig. 10, E). Questi risultati supportano il ipotesi che l'attività spontanea 'sorge' in un nervo periferico demielinizzato, fenomeno, appunto, chiamato efaptico.<ref name=":1" />
In conclusion, the patient was affected by 'Hemimasticatory Spasm' mainly focused on the right masseter muscle but with indirect diffusion of the phenomenon to the right temporal muscle probably due to hepaptic activity due to the demyelination of the masticatory motor nerves in the infratemporal fossa. Botulinum endotoxin therapy was started immediately with total regression of the disease 10 years later.


{{Q2|In conclusione la paziente era affetta da 'Spasmo Emimasticatorio' principalmente focalizzato sul muscolo massetere destro ma con diffusione indiretta del fenomeno al muscolo temporale destro probabilmente a causa di attività efaptiche dovute alla demielinizzazione dei nervi motori masticatori in fossa infratemporale. La terapia con endotossina botulinica fu iniziata immediatamente con regressione totale della malattia a 10 anni di distanza.}}
{{Q2|But how do we get to decrypt a machine language code?|we will try to describe it in the chapter 'Crypted code: Ephaptic transmission' at the end of the section 'Hemasticatory spasm'}}


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[[Category:Articles about logic of language]]
[[Category:Articles about logic of language]]

Latest revision as of 16:45, 19 October 2024

1° Clinical case: Hemimasticatory spasm

Abstract: This chapter, part of a series on medical diagnostics, focuses on the challenging diagnosis and treatment of "Hemimasticatory Spasm" in Mary Poppins. After enduring ten years of uncertainty and numerous tests across various disciplines, including dentistry and neurology, her case highlights the need for refined diagnostic approaches that integrate mathematical models and advanced neurophysiological understanding.

The narrative emphasizes the limitations of conventional diagnostic frameworks, often hindered by deterministic thinking that fails to capture the nuances of human physiology. The chapter advocates for integrating quantum probability and fuzzy logic into medical diagnostics, proposing a shift toward a more probabilistic interpretation of patient symptoms and test results. This approach reflects the complex nature of many medical conditions and promotes more accurate and individualized patient care.

Mary Poppins' diagnosis was complicated by overlapping symptoms and the unclear boundary between dental and neurological issues. Traditional diagnostic methods fell short, leading to prolonged suffering. The introduction of the "ephaptic transmission" concept—a nuanced understanding of nerve communication—highlights the importance of sophisticated diagnostic tools and models to differentiate similar symptoms caused by different conditions.

The chapter critiques outdated medical paradigms that compartmentalize conditions into narrowly defined categories, often ignoring the broader systemic nature of many disorders. By invoking Thomas Kuhn's theory of scientific revolutions, the text challenges the medical community to reconsider existing models and adopt approaches that address human health complexities.

Moreover, the chapter discusses the role of "fuzzy logic" in diagnostics, allowing for a range of possibilities rather than binary outcomes. This is particularly relevant for neurological disorders, where symptoms can be transient or vary in intensity.

Mary Poppins' journey through the medical system, marked by misdiagnoses and partial treatments, exemplifies the consequences of inadequate diagnostic models. Her eventual correct diagnosis, facilitated by understanding "ephaptic transmission" within her trigeminal system, underscores the potential for improved outcomes with innovative, interdisciplinary approaches.

In conclusion, the chapter calls for a paradigm shift in medical diagnostics. It argues for moving away from mechanical interpretations of diseases like malocclusions to a holistic, system-oriented view incorporating neurophysiology and quantum mechanics. This shift promises better diagnostic accuracy and aligns more closely with the complex reality of human biology, potentially revolutionizing healthcare.

The chapter concludes by emphasizing continuous education and openness to new ideas among medical professionals, suggesting that integrating diverse scientific insights and emerging technologies into clinical practice is crucial for effective treatment.

 

Introduction

From what has been exposed in the previous chapters from the 'Introduction' to the 'Logic of medic language' chapters, beyond the complexity of the arguments and the vagueness of the verbal language, we found ourselves faced with a dilemma that of the context in which the patient is referred and in these cases for our poor Mary Poppins it seems to dominate the dental context, given the positive assertions reported by the clinical and laboratory tests performed on the patient.

«then the dentist triumph!»
(it would seem apparently but ......)

The clinical case of our poor Mary Poppins shows all the physiopathological and clinical complexity but above all a phenomenon of overlapping of propositions, statements and logical phrases in the dental and neurological context in which, one context obtains compatibility and coherence while the other incoherence.

Basically, given the compatibility and consistency of sentence (dental context) with the assertions derived from the clinical test reporting , consistently say that Orofacial Pain is caused by a Temporomandibular Disorder could become incompatible if another set of clinical statements were consistent with sentence (neurological context) and contextually opposite, from a diagnostic point of view, to

Therefore, there would be a source of logistical conflict between the two specialist contexts with inevitable diagnostic delay, also polluting the decryption process of the signal in the machine language of the Central Nervous System (CNS).

What will determine the access key for decoding the encrypted code in machine language (SNC) and will allow us to intercept a demarcation line will be an irrefutable clinical and / or laboratory data called , which will confirm or exclude the consistency of an assertion than the other. It is essential, at this point, a sentence (demarcation sentence) of the type will be:

Does Mary Poppins have a neuromotor disorder or a Temporomandibular Disorder?

We explain this step in detail:

Remember that da 'The logic of classical language' this shows :

  • A set of sentences, and a number of other statements they are logically compatible if, and only if, the union between them it is consistent
  • A set of sentences, and a number of other statements they are logically incompatible if, and only if, the union between them it is inconsistent

Significance of the contexts

The dental context

Now, for the dental context we will have the following sentences and assertions to which we give a numerical value to facilitate the treatment and that is where indicates' normality' and 'abnormality' and therefore positivity of the report:

Positive radiological report of the TMJ in Figure 2, Abnormality, positivity of the report

Positive CT report of the TMJ in Figure 3, Abnormality, positivity of the report

Positive axiographic report of the condylar traces in Figure 4, Abnormality, positivity of the report

Asymmetric EMG interference pattern in Figure 5, Abnormality, positivity of the report

The sentence (dental context) with a number of other logically compatible assertions determine the union and coherence between them and are represented with a mathematical formalism to facilitate the diagnostic dialectic in the following way:


which represents the average of the individual statements reported. The average was designed because it can often happen that some tests give negative answers to which to give the value

The result in this case is and at the same time it derives the coherent statement of the sentence in which it is argued that the symptomatology of the patient Mary Poppins is determined by the presence of a DTMs.

«But, paradoxically, in the neurological context we will have the same rational process:»
(and it is precisely here that the contexts conflict)

The neurological context

In the neurological context, therefore, we will have the following sentences and assertions to which we give a numerical value to facilitate the treatment and that is where indicates 'normality' and 'abnormality' and therefore positivity of the report:


 Absence of jaw jerk in Figures 6, Abnormality, positivity of the report

 Absence of the silent masseterine period in Figures 7, Abnormality, positivity of the report

 Hypertrophy of the right masseter on CT in Figures 8, Abnormality, positivity of the report

Now consequently also sentence with a number of other logically compatible statements determine the union and coherence between them and the formal representation will be similar to that of the dental context:


with contextual coherent affirmation of sentence in which it is argued that the symptomatology of the patient Mary Poppins has a neuromotor cause and the clinical consequences of a masticatory occlusal type are nothing other than a consequence of the neuropathic damage.

«In this scenario both the statements and are compatible, consistent and therefore true until a 'demarcator of coherence' is found which we previously called »

Demarcator of coherence

The is a representative clinical specific weight, complex to research and fine-tune because it varies from discipline to discipline and for pathologies, essential in order not to make logical assertions collide and in the diagnostic procedures and essential to initialize the decryption of the logic communication code. Basically it allows you to confirm the consistency of a union with respect to another and vice versa, giving greater weight to the severity of the statements and the report in the appropriate context.

Sometimes the physician is faced with a series of positive reports to which to give due weight, he must consider the positivity of a report that highlights, for example, an osteoarticular remodeling of the TMJ cannot have the same weight as a positivity of a report confirming a latency delay of a trigeminal reflex.

The weight of demarcation , therefore, gives more significance to the most serious assertions in the clinical context from which they derive and therefore beyond the positivity of the or assertions which in any case are always verified and respected, these must be multiplied by a where indicates 'Low severity' while 'High severity'.

In the neurological context, concerns the presence of delays and/or latency absence of the jaw jerk, duration and/or absence of the masseterine silent period as well as other parameters that for the moment it is not necessary to describe. A delay greater than the normative value or an absence of the aforementioned tests is considered as a serious and absolute specific weight corresponding to a dominant valence with respect to the other clinical context.

To recap we therefore have:

where

average of the value of clinical statements in the dental context and therefore

average of the value of clinical statements in the neurological context and therefore

low severity performance of the dental contextreporting of high severity of the neurological context

where the 'coherence marker '' will define the diagnostic path as follows


«This formal logic syntax procedure allowed us to eliminate the interference of low clinical severity assertions and quickly define a neurological rather than dental diagnostic path through the definition of »

Once we have washed away the myriad of positively reported normative data, which generate conflicts between contexts, thanks to the coherence marker we have a much clearer and more linear picture on which to deepen the analysis of the functionality of the Central Nervous System. Consequently we can concentrate on intercepting the tests necessary to decrypt the machine language code that the SNC sends out converted into verbal language.

Ephaptic transmission

With a little effort and patience on the part of passionate readers who have followed the entire logical path, sometimes apparently off topic, we have reached a clinical picture in which the code to be decrypted is inherent in neuromotor damage. Consequently, the access keys to the code, the one that figuratively corresponds to the exact decryption algorithm, would correspond to the right choice of the neuromotor damage detector test.

This is a point where it is essential to infer the clinician's intuition because finding the right algorithm to decrypt the code, after the aforementioned filter steps that have been described to wash away the interference of assertions, means at least choosing the right dictionary, for example, that of the image (MR of the brain rather than the neck); acoustic and vestibular evoked potentials (if a vestibular scwannoma is suspected) or trigeminal electrophysiological study (if more than one trigeminal involvement is suspected).

In this clinical iter that we have presented, the choice of the clinician to follow the electrophysiological trigeminal roadmap from which the positivity of the assertions have already been derived, therefore, having already defined a picture of serious anomaly of absence of the jaw jerk and of the silent period masseterino on the right side of the patient will have to understand if the damage is intracranial or extracranial.

To do this, the clinician uses an electrical stimulation test of the masseter nerve in infratemporal fossa called on the masseter muscle with simultaneous recording of the heteronymous on the temporal muscle[1] and a bilateral transcranial electrical stimulation of the trigeminal motor roots called, precisely, [2]

M-wave

The right masseter nerve was electrically stimulated in the infratemporal fossa (see clinical procedure chapter: Encrypted code: Ephaptic transmission) with a technique similar to that described by Macaluso & De Laat (1995).[3] Square cathode pulses (0.1 ms) generated by an electrical stimulator (Neuropack X1, Nihon Kohden Corporation, Tokyo, Japan) were delivered through a Teflon-coated monopolar needle electrode (TECA 902-DMG25, 53534) with a tip non-isolated (diameter 0.36 mm; area 0.28 mm2) inserted 1.5 cm through the skin below the zygomatic arch and anterior to the temporomandibular joint in the infratemporal fossa with electrical shocks of 0.5 - 5 mA, and 0.1 ms. The anode was a surface non-polarizable Ag-AgCl disc electrode (OD 9.0 mm) positioned over the ipsilateral ear lobe. Electrical stimulation of the masseter nerve never produced pain, and the subjects only perceived muscle contraction. The correct position of the stimulation electrodes was monitored throughout the experimental session by checking online the size of the M wave in the masseter muscle. The signals were recorded by placing surface electrodes on the masseter and temporal muscles and filtered at 10-2000Hz and by concentric needle electrodes inserted into the anterior temporal muscle.

«The response in the right masseter was clearly delayed but relatively symmetrical in amplitude between sides. (Fig. 9)»

bRoot-MEPs

The trigeminal root was stimulated transcrally through high voltage, low impedance through an electrical stimulator (Neuropack X1, Nihon Kohden Corporation, Tokyo, Japan)) with the anode electrode positioned at the apex and the cathode approximately 10 cm laterally from the apex along a line vertex acoustic meatus. The electric field is believed to excite the trigeminal motor nerve fibers via the trancranial route, near their exit from the skull.[2][4] Also in this case, the response in the right masseter was markedly delayed (3.5 ms on the right side 2 ms on the left and dispersed. amplitude of the M-wave.


Figure 9: The responses evoked by stimulation of the masseter nerve M-wave and the trigeminal Root-MEPs are clearly delayed on the right side while maintaining the amplitude relatively symmetrical.


Having highlighted, through the execution of the and test, a delay in the conduction speed of the trigeminal nerve fibers generates the suspicion that it is a focal demyelination. This indicates that the problem is to be referred to the nervous component rather than to the muscular one, therefore, our attention should focus on the type of focal demyelination, extent of damage and presumably localization of the damage. The differential diagnosis at this point focuses on the type and area of the demyelinating damage, for example, if it is a damage exclusively referred to the masseterine motor nerve or the motor nerve of the temporal muscle is also involved, important for treatment with botulinum endotoxin. To resolve this doubt it is necessary to evoke a heteronymous response from recording on the temporal muscle.

H-wave

The arrangement is similar to that previously described with regard to the with the variant that the temporal muscle is recorded simultaneously with the stimulation of the masseterine nerve in the intratemporal fossa by a bipolar needle electrode. The stimulation must be gradually adapted in order to evoke both a from the masseter that a heteronymous from the temporal muscle.

In our patient Mary Poppins, unfortunately, the neuromotor situation is quite complex and serious because to the infratemporal stimulation of the masseteral nerve we have a direct evoked response on the muscle ipsilateral to the stimulation (figure 10; ) and at the same time not a heteronymous response (figure 10; ) on the temporal muscle but rather a tonic asynchronous activity (Figure )

This neurophysiopathological phenomenon is called 'Ephaptic transmission' and allows us to confirm the presence of demyelinating lesions also of the motor nerve of the temporal muscle.

As previously mentioned and in order not to burden the topic, the detailed description of the 'Hephaptic' phenomenon will be treated in the chapter 'Encrypted code: Ephaptic transmission' in order to better understand the physiological responses of heteronymous by pathological ones.


Figure 10: On the left side indicated with EMG the recording of the motor unit discharge on the right masseter at the time of the spasm is shown while on the right below indicated with M-wave we can see two motor potentials evoked by the electrical stimulation in infratemporal fossa recorded on the masseter. With H-wave it is possible to note the recording of the heteronomous H-wave on the temporal ipsilateral to the stimulation.

Conclusions

Following this step by step path we have demonstrated a peripheral motor nerve injury as originally proposed by Kaufman.[5] Conduction studies have shown a slowing of conduction in the extracranial course of masticatory nerve fibers without a reduction in the amplitude of and obviously EMG signs of chronic denervation. The temporal muscle biopsy appeared histologically normal.

«These results indicate axon-sparing demielination.»

The absence of the jaw jerk on the diseased side indicates damage to the large diameter afferent fibers () from the neuromuscular spindles. A lesion of few afferents could easily abolish the jaw jerk.[6]

Muscle nerve damage would not be explained only because patients with Hemimasticatory Spasm (HMS) do not have sensory disturbances but also because they often only have spasms in one or two levator mandibular muscles. These observations argue against damage to the motor root or to the intracranial portion of the mandibular nerve where the motor bundles are closely grouped,[7] favoring damage to the individual muscle nerves that pass through the infratemporal fossa.

The mechanism of involvement of facial paroxysmal involuntary activity has been discussed by Kaufnan[5] and by Thompson and Carroll[8] who emphasized the close similarity between hemimasticatory and hemifacial spasm.

In EMG, these prolonged spasms fit perfectly into the description of cramps, that is, discharges of irregular motor units that progressively increase, leading to the recruitment of much of the muscle of synchronous discharges at speeds of 40 to 60 Hz.[9] Common to hemifacial spasm and cramps however, ectopic EMG activities can also be detected.

This could be responsible for the high frequency of EMG discharges at a frequency of 100-200 Hz and the synchronization of the entire muscle or multiple muscles, and post-activity. The synchronization could be explained by the lateral spread of discharges from adjacent nerve fibers,[10][11] generating a local re-excitation circuit. Posthumous EMG activity consists of paroxysmal discharges that may follow a voluntary orthodromic contraction or antidromic impulses,[12][13] and is attributed to self-excitation of the same axons after the passage of an impulse.


In our patient Mary Poppins we observed a synchronization of the whole or a large part of the muscle involved in the spasm (fig 10, EMG); the self-excitation is evidenced by the recording of the evoked discharges following the response of the stimulation of the chewing nerves (Fig. 10, E). These results support the hypothesis that spontaneous activity 'arises' in a demyelinated peripheral nerve, a phenomenon called hepaptic.[13]

In conclusion, the patient was affected by 'Hemimasticatory Spasm' mainly focused on the right masseter muscle but with indirect diffusion of the phenomenon to the right temporal muscle probably due to hepaptic activity due to the demyelination of the masticatory motor nerves in the infratemporal fossa. Botulinum endotoxin therapy was started immediately with total regression of the disease 10 years later.

«But how do we get to decrypt a machine language code?»
(we will try to describe it in the chapter 'Crypted code: Ephaptic transmission' at the end of the section 'Hemasticatory spasm')
Bibliography & references
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