Modern approaches to osteopathic diagnostics, its theoretical and practical foundations

The article presents the main osteopathic tests that allow identifying and differentiating biomechanical, hydrodynamic and neurodynamic components of somatic dysfunctions and choosing adequate techniques for osteopathic correction. For each test, an anatomical and physiological justifi cation is given and the principle of its implementation is described.

1. Mokhov D. E., Aptekar I. A., Belash V. O., Litvinov I. A., Mogelnitsky A. S., Potekhina Yu. P., Tarasov N. A., Tarasova V. V., Tregubova E. S., Ustinov A. V. The basics of osteopathy: A textbook for residents. M.: Geotar-Media; 2020; 400 p. (in russ.).

2. DO versus MD: how much does medical school degree type. Accessed in January 30, 2022 https://www.ama-assn.org/residents-students/preparing-medical-school/do-vs-md-how-much-does-medical-school-degree-type

3. Order of the Ministry of Health of the Russian Federation of November 2, 2020 № 1186n «On Amendments to the Order of the Ministry of Health of the Russian Federation of December 15, 2014 № 834n „On Approval of Unifi ed Forms of Medical Records Used in Medical Organizations Providing Medical Care on an Outpatient basis, and Procedures for their completion“». Accessed in March 31, 2022 (in russ.)]. http://publication.pravo.gov.ru/Document/View/0001202011270030

4. Mokhov D. E., Potekhina Yu. P., Tregubova E. S., Gurichev A. A. Osteopathy — a new direction of medicine (modern concept of Osteopathy). Russian Osteopathic Journal. 2022; 2: 8–26 (in russ.).

5. Mokhov D. E., Belash V. O., Kuzmina Ju. O., Lebedev D. S., Miroshnichenko D. B., Tregubova E. S., Shirjaeva E. E., Yushmanov I. G. Osteopathic Diagnosis of Somatic Dysfunctions: Clinical Recommendations. St. Petersburg: Nevskiy rakurs; 2015; 90 p. (in russ.).

6. Barral J.-P., Mercier P. Visceral manipulation. Part 1. St. Petersburg: Publishing House «Institute of Clinical Applied Kinesiology»; 2015; 227 p. (in russ.).

7. Slesarev V. I. Water: a substance with unique properties. Hygiene and Sanitation. 2021; 100 (1): 19–24 (in russ.). https://doi.org/10.47470/0016-9900-2021-100-1-19-24

8. Sudakov K. V. Normal physiology: textbook. M.: GEOTAR-Media; 2015; 880 p. (in russ.).

9. Dubrovsky V. I., Fedorova V. N. Biomechanics: A textbook. M.: VLADOS-PRESS; 2003; 672 p. (in russ.).

10. Heymann J. B., Agre P., Engel A. Progress on the Structure and Function of Aquaporin 1. J. Struct. Biol. 1998; 121 (2): 191–206. https://doi.org/10.1006/jsbi.1997.3951

11. Koestler A. Spirit in the car. Questions of Philosophy. 1993; 10: 93–122 (in russ.).

12. Tricot P. Tissue approach in osteopathy. Book 2. Healer of Consciousness: Guide for doctors. St. Petersburg: Publishing house MPB MAPO; 20011; 416 p. (in russ.).

13. Wilber K. A Brief History of Everything. M.: AST—Astrel; 2006; 476 p. (in russ.).

14. Borodin Yu. I. The lymph in the intracorporal circuit of the water. Bull. SB RAMS. 2014; 34(1): 10–14 (in russ.).

15. Földi M., Csanda E., Simon M., Obál F., Schneider I., Dobranovics I., Zoltán O. T., Kozma M., Poberai M.. Lymphogenic haemangiopathy. «Prelymphatic» pathways in the wall of cerebral and cervical blood vessels. Angiologica. 1968; 5 (4): 250–262.

16. Casley-Smith J. R., Földi-Börcsök E., Földi M. A fi ne structural study of the tissue channels′ numbers and dimensions in normal and lymphoedematous tissues. Z. Lymphol. 1979; 3 (1): 49–58.

17. Zhdanov D. A. General anatomy and physiology of the lymphatic system. L.: Medgiz; 1952; 333 p. (in russ.).

18. Bockeria L. A., Vyrenkov Yu. E. Lymphatic system of the heart. M.: A. N. Bakulev NMRCVS; 2005; 186 p. (in russ.).

19. Parsons D., Marser N. Osteopathy. Models for diagnosis, treatment and practice. St. Petersburg: Meridian-S; 2010; 469 p. (in russ.).

20. Chikly B. Silent Waves. IHH Pub. AZ. 2004; 119 p.

21. Liem T., Dobler T. K. Guide to structural osteopathy. M.: Eksmo; 2019; 704 p. (in russ.).

22. Kimelberg H. K. Water homeostasis in the brain: Basic concepts. Neuroscience. 2004; 129 (4): 851–860. https://doi.org/10.1016/j.neuroscience.2004.07.033

23. Magouliotis D. E., Tasiopoulou V. S., Svokos A. A., Svokos K. A. Aquaporins in health and disease. Adv. Clin. Chem. 2020; 98: 149–171. https://doi.org/10.1016/bs.acc.2020.02.005

24. Louveau A., Smirnov I., Keyes T. J., Eccles J. D., Rouhani S. J., Peske J. D., Derecki N. C., Castle D., Mandell J. W., Lee K. S., Harris T. H., Kipnis J. Structural and functional features of central nervous system lymphatic vessels. Nature. 2015; 523 (7560): 337–341. https://doi.org/10.1038/nature14432

25. Aspelund A., Antila S., Proulx S. T., Karlsen T. V., Karaman S., Detmar M., Wiig H., Alitalo K. A dural lymphatic vascular system that drains brain interstitial fl uid and macromolecules. J. exp Med. 2015; 212 (7): 991–999. https://doi.org/10.1084/jem.20142290

26. Plog B. A., Nedergaard M. The Glymphatic System in Central Nervous System Health and Disease: Past, Present, and Future. Ann. Rev. Pathol. Mech. Dis. 2018; 13 (1): 379–394. https://doi.org/10.1146/annurev-pathol-051217-111018

27. Iliff J. J., Wang M., Liao Y., Plogg B. A., Peng W., Gundersen G. A., Benveniste H., Vates G. E., Deane R., Goldman S. A., Nagelhus E. A., Nedergaard M. A Paravascular Pathway Facilitates CSF Flow Through the Brain Parenchyma and the Clearance of Interstitial Solutes, Including Amyloid. Sci. Transl. Med. 2012; 4 (147): 147ra111–147ra111. https://doi.org/10.1126/ scitranslmed.3003748

28. Bucchieri F., Farina F., Zummo G., Cappello F. Lymphatic vessels of the dura mater: a new discovery? J. Anat. 2015; 227 (5): 702–703. https://doi.org/10.1111/joa.12381

29. Pesin Y. M., Omorov N. K., Doronin B. M. Considering the question about spinal liqiud′s outfl ow to the lymphatic channel. Bull. Siberian Med. 2009; 8 3(2): 27–29 (in russ.). https://doi.org/10.20538/1682-0363-2009-3(2)-27-29

30. Ring F., Jung A., Zuber J. New opportunities for infrared thermography in medicine. Acta BioOptica Inform. Med. 2009; 15 (1): 28–30.

31. Durnovo E. A., Potekhina Yu. P., Marochkina M. S., Yanova N. A., Sahakyan M. Y., Ryzhevsky D. V. Diagnostic Capabilities of Infrared Thermography in the Examination of Patients with Diseases of Maxillofacial Area. Modern Technol. Med. 2014; 6 (2): 61–67 (in russ.).

32. Tarasova A. V., Potekhina Yu. P., Belash V. O., Klassen D. Ya. The application of infrared thermography for the objectifi cation of somatic dysfunctions and osteopathic correction results. Manual Ther. J. 2019; 4 (76): 35–41 (in russ.).

33. Belash V. O. The possibilities of using local thermometry to objectify the effect of osteopathic correction in patients with dorsopathy at the cervicothoracic level. Russian Osteopathic Journal. 2018; 3–4: 25–32 (in russ.)]. https://doi.org/10.32885/2220-0975-2018-3-4-25-32

34. Zeveke A. V., Ashutov A. N., Gushchina Yu. Yu., Mokrov Ya. P., Plokhov R. A. Thermomechanical and structural properties of collagen and its role for skin mechanoreceptors irritation. Almanac clin. Med. 2006; 12: 114 (in russ.).

35. Zeveke A. V. Mechanism of formation of codes by touch. Nizhny Novgorod Med. J. 2003; 1: 47 (in russ.).

36. Zeveke A. V. About theory of skin sensitivity. Sensory syst. 2004; 18 (1): 21–30 (in russ.).

37. Hensel H., Schäfer K. Static an dynamic activity of cold receptors in cats after long-term exposure to various temperatures. Pfl ugers Arch. 1982; 392 (3): 291–294. https://doi.org/10.1007/BF00584313

38. Medvedev A. A., Sokolova L. V. Features and mechanisms of temperature sensitivity (review). J. med. biol. Res. 2019; 7 (1): 92–105 (in russ.). https://doi.org/10.17238/issn2542-1298.2019.7.1.92

39. Studenikina T. M., Sluka B. A. Embryology: Tutorial. Minsk: Harvest; 2009; 304 p. (in russ.).

40. Zaguskin S. L. Time Life and Biosystems Sustainability. Part 1. Preservation of Biosystems Stability through Deletion or Update Its Components. Space and Time. 2012; 4 (10): 168–174.

41. Zaguskin S. L. Cell rhythms and human health. Rostov-on-Don: SFU; 2010; 292 p. (in russ.).

42. Auberville A., Aubin A. Motility in osteopathy. A new concept based on embryology. M.: Pract. Med.; 2017; 192 p. (in russ.).

43. Rukan T. A., Maksimovich N. E., Zimatkin S. M. Morphofunctional changes in the neurons of the frontal cerebral cortex of rats under its ischemia-reperfusion. J. Grodno SMU. 2012; 4 (40): 35–38 (in russ.).

44. Yakhno N. N., Kukushkin M. L., Churyukanov M. V., Davydov O. S., Bakhtadze M. A. New defi nition of pain by the International Association for the Study of Pain. Russ. J. Pain. 2020; 18 (4): 5–7 (in russ.). https://doi.org/10.17116/pain2020180415

45. Treede R. D., Rief W., Barke A., Aziz Q., Bennett M. I., Benoliel R., Cohen M., Evers S., Finnerup N. B., First M. B., Giamberardino M. A., Kaasa S., Kosek E., Lavand′homme P., Nicholas M., Perrot S., Scholz J., Schug S., Smith B. H., Svensson P., Vlaeyen J. W. S., Wang S. J. A classifi cation of chronic pain for ICD-11. Pain. 2015; 156 (6): 1003–1007. https://doi.org/10.1097/j.pain.0000000000000160

46. Toth C. Peripheral and Central sensitization // In: Neuropathic Pain: Causes, Management, and Understanding / Eds. C. Toth, D. E. Moulin. Cambridge: Cambridge University Press; 2013; 378 p.

47. Danilov A. B., Davydov O. S. Neuropathic pain. M.: Borges; 2007; 190 p. (in russ.).

48. Yamada K., Matsudaira K., Imano H., Kitamura A., Iso H. Infl uence of workrelated psychosocial factors on the prevalence of chronic pain and quality of life in patients with chronic pain. Brit. med. J. Open. 2016; 6 (4): e010356. https://doi.org/10.1136/bmjopen-2015-010356

49. Danilov Al. B., Isagulyan E. D., Mackaschova E. S. Psychogenic pain. S. S. Korsakov J. Neurol. Psychiat. 2018; 118 (11): 103–108 (in russ.)]. https://doi.org/10.17116/jnevro2018118111103

50. Karcioglu O., Topacoglu H., Dikme O., Dikme O. A systematic review of the pain scales in adults: Which to use? Amer. J. Emerg. Med. 2018; 36 (4): 707–714. https://doi.org/10.1016/j.ajem.2018.01.008

51. Carbajal R., Paupe A., Hoenn E., Lenclen R., Olivier Martin M. DAN une échelle comportementale d′évaluation de la douleur aiguë du nouveau-né. Arch. Pediat. 1997; 4 (7): 623–628.

52. Belyaev A. F., Karpenko N. A. Pain syndromes in newborns. Russ. J. Pain. 2017; 3–4 (54): 60–63 (in russ.).

53. Орлов В. А., Стрижакова О. В. Нервно-мышечная сила как один из важнейших показателей здоровья и работоспособности человека. Вестн. новых мед. технологий (электронное издание). 2020; 3: Публикация 3–1. Ссылка активна на 31.03.2022. http://www.medtsu.tula.ru/VNMT/Bulletin/E2020-3/3-1.pdf

54. Medical Research Council. Aids to the examination of the peripheral nervous system. Memorandum no. 45. Her Majesty′s Stationery Offi ce. London; 1981.

55. Воронов А. В., Хиснутдинова Д. Р. Теоретическая и экспериментальная оценка силы тяги головок трехглавой мышцы голени при разгибании голеностопного сустава. Вестн. спорт. науки. 2011; 4: 44–55.

56. Чындын-Оол Э. С., Павлов В. В., Самохин А. Г. Разгибательно-отводящая контрактура тазобедренных суставов как следствие фиброза ягодичных мышц (обзор литературы). Гений ортопедии. 2021; 27 (5): 658–668. https://doi.org/10.18019/1028-4427-2021-27-5-658-668

57. Odinak M. M., Dyskin D. E. Clinical diagnostics in neurology: Guide for doctors. St. Petersburg: Spetslit; 2010; 528 p. (in russ.).

58. Bernstein N. A. Essays on the physiology of movements and the physiology of activity. M.: Medicine; 1966; 350 p. (in russ.).

59. Physiology of movements / Eds. M. A. Alekseev, V. S. Gurfi nkel, P. G. Kostyuk et al. L.: Science; 1976; 375 p. (in russ.).

60. Bernstein N. A. Physiology of movements and activity. M.: Nauka; 1990; 494 p. (in russ.).

61. Aleksandrov A. V., Frolov A. A. The organization of the feed-forward motor control during human upper trunk bending. Russ. J. Biomech. 2010; 14 (3): 19–35 (in russ.).

62. Neurophysiology: interhemispheric asymmetry of the human brain (right-handed–left-handed) / Ed. L. A. Zhavoronkov. M.: Yurayt; 2019; 217 p. (in russ.).