Certificado en Terapia Manual Espinal by Manual Concepts (CSMT)

Kim Robinson y Toby Hall son los fundadores y los directores de Manual Concepts. Esta organización fue establecida para desarrollar y proporcionar un nivel de excelencia en la educación de terapia manual para fisioterapeutas. A través de su experiencia en esta área, Kim y Toby han sido galardonados con los puestos de Fisioterapeutas Musculoesqueléticos Especializados (Fellowship concedido por el Colegio Australiano de Fisioterapeutas en 2007), así como puestos como Profesor Asociado Adjunto y Senior Teaching Fellows en Curtin University of Technology y Senior Teaching Fellow en la Universidad del Oeste de Australia.

El curso cubrirá las bases anatómicas, fisiológicas y funcionales para la evaluación de los trastornos del dolor de la columna vertebral.

De especial interés será la práctica clínica, haciendo hincapié en el examen clínico, la evaluación, la interpretación, diagnóstico diferencial y manejo del mismo. La práctica basada en la evidencia es un componente esencial del programa.

Este curso enfatiza un enfoque basado en la evidencia para la terapia manual espinal,

incorporando la clasificación de los trastornos del dolor espinal y la consiguientes subcategorias basadas en la aplicación de estrategias de terapia manual.

Este curso se llevará a cabo en formato de conferencia, tutorial y taller para el fisioterapeuta que esté interesado en terapia manual, medicina manual o medicina musculoesquelética. Se anticipa que el contenido del curso será adecuado a las personas que buscan nuevos conocimientos, a las personas que buscan expandir su conocimiento y a esas personas

buscando la estimulación de la interacción clínica. Si bien el curso se presentará como un nivel alto, esto no debería verse como una barrera para la participación de aquellos con poca o ninguna experiencia previa en esta área específica. Como resultado de

Al asistir al curso, se anticipa que los participantes obtendrán satisfacción personal de diversas maneras que mejorar sus requisitos individuales. Por lo tanto, no hay requisitos previos para la participación.

Sistema articular:

Como parte de la evaluación del sistema articular, nuestro objetivo es enseñar una gama de pruebas articulares incluyendo pruebas de provocación de dolor para estructuras específicas, así como pruebas para determinar qué segmento especifico tiene la disfunción motora.

Un aspecto significativo del procedimiento de evaluación es el uso de movimientos combinados. Igualmente importante es el uso de pruebas específicas de movimiento segmentario pasivo y pruebas provocativas de dolor. La investigación actual demuestra que la identificación de la hipo / hiper movilidad articular y el tratamiento posterior basado en esta clasificación mejora los resultados del tratamiento.

Sistema neuronal:

El desorden del sistema neural es común en trastornos de dolor musculoesquelético, por lo que el examen del sistema neural constituye un elemento esencial de la exploración física. Sin embargo, no todos los trastornos neuronales responden a las técnicas de movilización neuronal. Por lo tanto, es esencial que el profesional comprenda bien los mecanismos fisiopatológicos subyacentes a los problemas de dolor neural para comprender cómo manejarlos de manera efectiva. Como parte del curso, se presentará una descripción general de los trastornos del dolor del tejido neural para permitir el diagnóstico diferencial y la clasificación de 3 subclasificaciones específicas de tratamiento:

• Dolor neuropático con hipersensibilidad sensorial
• Sensibilización del tronco nervioso periférico y
• Dolor neuropático con compresión de la raíz nerviosa (daño fascicular).

La evaluación para identificar estos problemas será demostrada y practicada.

Sistema muscular:

El énfasis de este programa es un enfoque funcional para la evaluación del control motor espinal. Asimismo, abordamos el concepto teórico de la inestabilidad espinal y los signos y síntomas que se encuentran comúnmente en el examen clínico del deterioro del control motor. Es importante reconocer que no todos los pacientes requieren un entrenamiento de control motor. Existe amplia evidencia para sugerir que solo una pequeña proporción de pacientes padecen inestabilidad. Tratar todos los pacientes con dolor lumbar crónico con ejercicios de estabilización a través de ejercicios específicos del multífido y transverso del abdomen no es apropiado y la literatura científica lo demuestra. Determinar qué pacientes requieren reeducación del control motor es una parte importante del programa. Se enseñará un enfoque sistemático gradual y funcional para el tratamiento de pacientes con deterioro del control motor espinal.

Un principio central del programa es el análisis continuo de los resultados tras los procedimientos subjetivos y físicos de evaluación/valoración. Para determinar un diagnóstico de terapia manual apropiado, el análisis crítico se desarrolla mediante el razonamiento clínico aplicado a estudios de casos específicos.

Este programa no proporciona a los participantes un enfoque-receta para el tratamiento. Con éste los profesionales podrán desarrollar una metodología sólida, estrategias de tratamiento apropiadas con progresión lógica a largo plazo.

Al finalizar el programa de ocho días, los participantes habrán adquirido la capacidad de

• Conocer los desarrollos clínicamente relevantes en anatomía, patoanatomía y cambios relacionados con la edad de la columna vertebral.
• Tener una comprensión clara de los mecanismos del dolor y su relevancia clínica, y obtener una comprensión adecuada de las medidas para abordar una variedad de trastornos agudos, crónicos y complejos del dolor.
• Conocer las pruebas actuales y los procesos de razonamiento clínico con respecto a la terapia manual espinal.
• Ser capaz de aplicar procedimientos de evaluación/valoración/examen de la articulación espinal, neural y muscular.
• Ser capaz de determinar un diagnóstico diferencial basado en un examen integrado de la articulación, los músculos y los sistemas neuronales de la columna vertebral y la pelvis.
• Ser capaz de formular el programa de tratamiento de terapia manual más apropiado y efectivo adecuándolo a lo anteriormente evaluado/valorado.
• Ser competente en la aplicación de una estrategia de tratamiento de terapia manual específica de diagnóstico apropiada que incorpore técnicas de tratamiento manual y ejercicios específicos.

Day 1

• 9.00 – Session 1: Introduction LBP. Evidence base for manual therapy. Lumbar pathophysiology
• 10.30 – Morning tea
• 10.50 – Session 2: Lumbar physical exam. Posture
• 12:30 – Lunch
• 13:30 – Session 3: Active mov’t, dynamic control + combined mov’t
• 15:00 – Afternoon tea
• 15:15 – Session 4: Active mov’t, dynamic control + combined mov’t
• 17:00 – Finish

Day 2

• 9.00 – Session 1: Lumbar spine segmental mobility tests
• 10.30 – Morning tea
• 10.50 – Session 2: Lumbar neural disorders
• 12:30 – Lunch
• 13:30 – Session 3: Lumbar neural assessment
• 15:00 – Afternoon tea
• 15:15 – Session 4: Sacroiliac joint assessment
• 17:00 – Finish

Day 3

• 9.00 – Session 1: Lumbar motor control impairment functional muscle assessment
• 10.30 – Morning tea
• 10.50 – Session 2: Treatment – lumbar articular dysfunction
• 12:30 – Lunch
• 13:30 – Session 3: Treatment –  lumbar articular dysfunction
• 15:00 – Afternoon tea
• 15:15 – Session 4: Treatment – lumbar articular dysfunction
• 17:00 – Finish

Day 4

• 9.00 – Session 1: Lumbar motor control impairment functional correction
• 10.30 – Morning tea
• 10.50 – Session 2: Neural treatment. Denervation & peripheral nerve sensitization
• 12:30 – Lunch
• 13:30 – Session 3: Neural treatment. Denervation & peripheral nerve sensitization
• 15:00 – Afternoon tea
• 15:15 – Session 4: Thoracic spine active movement & combined movement
• 17:00 – Finish

Day 5

• 9.00 – Session 1: Thoracic spine segmental mobility tests
• 10.30 – Morning tea
• 10.50 – Session 2: Thoracic cage assessment
• 12:30 – Lunch
• 13:30 – Session 3: Thoracic spine/cage articular treatment
• 15:00 – Afternoon tea
• 15:15 – Session 4: Thoracic spine/cage articular treatment
• 17:00 – Finish

Day 6

• 9.00 – Session 1: Cervical spine anatomy, age changes and pathoanatomy
• 10.30 – Morning tea
• 10.50 – Session 2: Active movement analysis + Upper Cx combined movement
• 12:30 – Lunch
• 13:30 – Session 3: Upper cervical spine segmental mobility tests
• 15:00 – Afternoon tea
• 15:15 – Session 4: Ucx stress tests Ucx Passive segmental mobility tests
• 17:00 – Finish

Day 7

• 9.00 – Session 1: Cervicothoracic motor control assessment
• 10.30 – Morning tea
• 10.50 – Session 2: Upper cervical treatment
• 12:30 – Lunch
• 13:30 – Session 3: Upper cervical treatment
• 15:00 – Afternoon tea
• 15:15 – Session 4: Lower cervical articular/neural assessment
• 17:00 – Finish

Day 8

• 9.00 – Session 1: Lower cervical articular/neural assessment
• 10.30 – Morning tea
• 10.50 – Session 2: Cervical neural/articular treatment techniques
• 12:30 – Lunch
• 13:30 – Session 3: Cervical neural/articular treatment techniques
• 15:00 – Afternoon tea
• 15:15 – Session 4: Cervical neural/articular treatment techniques
• 17:00 – Finish

1. Side-to-side range of movement variability in variants of the median and radial neurodynamic test sequences in asymptomatic people.
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6. The flexion-rotation test and active cervical mobility–a comparative measurement study in cervicogenic headache.Hall T, Robinson K.
7. Man Ther. 2004 Nov;9(4):197-202.PMID: 15522644
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19. Long-term stability and minimal detectable change of the cervical flexion-rotation test. Hall T, Briffa K, Hopper D, Robinson K. J Orthop
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21. Reliability of manual examination and frequency of symptomatic cervical motion segment dysfunction in cervicogenic headache. Hall T,
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22. A radiographic analysis of the influence of initial neck posture on cervical segmental movement at end-range extension in asymptomatic
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23. Normal kinematics of the upper cervical spine during the Flexion-Rotation Test – In vivo measurements using magnetic resonance imaging.
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26. Outcomes differ between subgroups of patients with low back and leg pain following neural manual therapy: a prospective cohort study.
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27. Reliability of thermal quantitative sensory testing of the hand in a cohort of young, healthy adults. Moloney NA, Hall TM, O’Sullivan TC,
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28. Muscle Nerve. 2011 Oct;44(4):547-52. doi: 10.1002/mus.22121. Epub 2011 Aug 8. PMID: 21826684
29. The influence of lower cervical joint pain on range of motion and interpretation of the flexion-rotation test. Hall T, Briffa K, Hopper D. J
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30. Inter-therapist agreement in classifying patients with cervical radiculopathy and patients with non-specific neck-arm pain. Tampin B, Briffa
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31. A pilot study to investigate the short-term effects of specific soft tissue massage on upper cervical movement impairment in patients with
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32. Use of kinematic algorithms to distinguish people with chronic non-specific low back pain from asymptomatic subjects: a validation study.
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33. The efficacy of manual therapy and exercise for different stages of non-specific low back pain: an update of systematic reviews. Hidalgo B,
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34. The clinical utility of pain classification in non-specific arm pain. Moloney NA, Hall TM, Leaver AM, Doody CM. Man Ther. 2015
Feb;20(1):157-65. doi: 10.1016/j.math.2014.08.010. Epub 2014 Sep 4. PMID: 25444375
35. Immediate effects of hip mobilization with movement in patients with hip osteoarthritis: A randomised controlled trial. Beselga C, Neto F,
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36. The Effect of the Mulligan Knee Taping Technique on Patellofemoral Pain and Lower Limb Biomechanics. Hickey A, Hopper D, Hall T, Wild
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37. International consensus on the most useful physical examination tests used by physiotherapists for patients with headache: A Delphi
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39. A normative study of cervical range of motion measures including the flexion-rotation test in asymptomatic children: side-to-side
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40. A new method of measuring shoulder hand behind back movement: Reliability, values in symptomatic and asymptomatic people, effect of
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41. Do subjects with acute/subacute temporomandibular disorder have associated cervical impairments: A cross-sectional study. von Piekartz
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45. Bilateral dorsal foot pain in a young tennis player managed by neurodynamic treatment techniques. Nelson R, Hall T. Man Ther. 2011
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46. Nucleus pulposus deformation following application of mechanical diagnosis and therapy: a single case report with magnetic resonance
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48. Orofacial manual therapy improves cervical movement impairment associated with headache and features of temporomandibular
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50. Efficacy of Hand Behind Back Mobilization With Movement for Acute Shoulder Pain and Movement Impairment: A Randomized Controlled
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51. Short-term effects of Mulligan mobilization with movement on pain, disability, and kinematic spinal movements in patients with
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55. Agreement and correlation between the self-report leeds assessment of neuropathic symptoms and signs and Douleur Neuropathique 4
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56. Intertester agreement and validity of identifying lumbar pain provocative movement patterns using active and passive accessory
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58. Effects of two different knee tape procedures on lower-limb kinematics and kinetics in recreational runners. Howe A, Campbell A, Ng L,
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59. Changes in cervical movement impairment and pain following orofacial treatment in patients with chronic arthralgic temporomandibular
disorder with pain: A prospective case series. Grondin F, Hall T. Physiother Theory Pract. 2017 Jan;33(1):52-61. doi:
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60. Dynamic soft tissue mobilisation increases hamstring flexibility in healthy male subjects. Hopper D, Deacon S, Das S, Jain A, Riddell D, Hall T, Briffa K. Br J Sports Med. 2005 Sep;39(9):594-8; discussion 598. PMID: 16118294
61. Agreement and correlation between the straight leg raise and slump tests in subjects with leg pain. Walsh J, Hall T. J Manipulative Physiol
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62. Interrater reliability of a new classification system for patients with neural low back-related leg pain. Schäfer A, Hall TM, Lüdtke K,
Mallwitz J, Briffa NK. J Man Manip Ther. 2009;17(2):109-17. PMID: 20046553
63. Neurodynamic treatment improves leg pain, back pain, function and global perceived effect at 4 weeks in patients with chronic nerverelated
leg pain. Hall T, Coppieters MW, Nee R, Schäfer A, Ridehalgh C. J Physiother. 2017 Jan;63(1):59. doi: 10.1016/j.jphys.2016.09.001.Epub 2016 Nov 5. No abstract available. PMID:27964965
64. Classification of low back-related leg pain: do subgroups differ in disability and psychosocial factors? Walsh J, Hall T. J Man Manip Ther. 2009;17(2):118-23. PMID: 20046554
65. Quantitative sensory testing somatosensory profiles in patients with cervical radiculopathy are distinct from those in patients with
nonspecific neck-arm pain. Tampin B, Slater H, Hall T, Lee G, Briffa NK. Pain. 2012 Dec;153(12):2403-14. doi: 10.1016/j.pain.2012.08.007.
Epub 2012 Sep 11. PMID: 22980746
66. Mobilization with movement, thoracic spine manipulation, and dry needling for the management of temporomandibular disorder: a
prospective case series. González-Iglesias J, Cleland JA, Neto F, Hall T, Fernández-de-las-Peñas C. Physiother Theory Pract. 2013
Nov;29(8):586-95. doi: 10.3109/09593985.2013.783895. Epub 2013 May 20.PMID: 23687913
67. Divergent sensory phenotypes in nonspecific arm pain: comparisons with cervical radiculopathy. Moloney N, Hall T, Doody C. Arch Phys
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68. Responses to mechanical stimulation of the upper limb in painful cervical radiculopathy. Hall T, Quintner J. Aust J Physiother.
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69. The late whiplash syndrome: a psychophysical study. Moog M, Quintner J, Hall T, Zusman M. Eur J Pain. 2002;6(4):283-94. PMID:
12161094
70. An investigation of somatosensory profiles in work related upper limb disorders: a case-control observational study protocol. Moloney N,
Hall T, Doody C. BMC Musculoskelet Disord. 2010 Jan 30;11:22. doi: 10.1186/1471-2474-11-22. PMID: 20113518 Free PMC Article
71. Reliability of thermal quantitative sensory testing: a systematic review. Moloney NA, Hall TM, Doody CM. J Rehabil Res Dev.
2012;49(2):191-207. Review. PMID: 22773522 Free Article
72. Sensory hyperalgesia is characteristic of nonspecific arm pain: a comparison with cervical radiculopathy and pain-free controls. Moloney
N, Hall T, Doody C. Clin J Pain. 2013 Nov;29(11):948-56. doi: 10.1097/AJP.0b013e31827c7ae8. PMID: 23370077
73. Is there a difference in head posture and cervical spine movement in children with and without pediatric headache? Budelmann K, von
Piekartz H, Hall T. Eur J Pediatr. 2013 Oct;172(10):1349-56. doi: 10.1007/s00431-013-2046-z. Epub 2013 May 26. PMID: 23708260
74. Patterns of cervical and masticatory impairment in subgroups of people with temporomandibular disorders-an explorative approach based
on factor analysis. Ballenberger N, von Piekartz H, Danzeisen M, Hall T. Cranio. 2017 Mar 20:1-11. doi: 10.1080/08869634.2017.1297904.
[Epub ahead of print] PMID: 28317439
75. Determinants of learning to perform spinal anaesthesia: a pilot study. Kulcsar Z, Aboulafia A, Hall T, Shorten GD. Eur J Anaesthesiol. 2008
Dec;25(12):1026-31. doi: 10.1017/S0265021508004535. Epub 2008 Jun 5. PMID: 18533064
76. Reconceptualising manual therapy skills in contemporary practice. Rabey M, Hall T, Hebron C, Palsson TS, Christensen SW, Moloney N.
Musculoskelet Sci Pract. 2017 Jun;29:28-32. doi: 10.1016/j.msksp.2017.02.010. Epub 2017 Mar 6. PMID: 28286240
77. Appropriateness of anteroseptal myocardial infarction nomenclature evaluated by late gadolinium enhancement cardiovascular magnetic
resonance imaging. Allencherril J, Fakhri Y, Engblom H, Heiberg E, Carlsson M, Dubois-Rande JL, Halvorsen S, Hall TS, Larsen AI, Jensen SE,
Arheden H, Atar D, Clemmensen P, Shah DJ, Cheong B, Sejersten M, Birnbaum Y. J Electrocardiol. 2017 Oct 6. pii: S0022-0736(17)30347-3.
doi: 10.1016/j.jelectrocard.2017.09.013. [Epub ahead of print] PMID: 29103621
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