The modular paradigm and the problem of the structural and functional organization of the tentorium

It is discussed topical issues of the organization of neural ensembles implementing the basic functions of the tentorium. On the basis of literature data and own research of the author the position substantiates according to which the actual existence of the cerebellar cortex has functional modules coordinates and their morphological contours determined by the core of the exciting influence of afferent fibers and local interneuron connections. The dynamic characteristics of the modules are considered by the example of the formation of ergic compartments of neurons and parasagittal corticonuclear microcomplexes of the tentorium; it is suggested the generalized scheme of these communications.

modular self-organization, corticonuclear microcomplex, models of interneuron connections

1. Калиниченко С.Г., Охотин В.Е. Униполярные кисточковые клетки - новый тип возбуждающих интернейронов коры мозжечка и улитковых ядер мозгового ствола // Морфология. 2003. Т. 124, № 6. С. 7-21.

2. Калиниченко С.Г., Мотавкин П.А. Кора мозжечка. М.: Наука, 2005. 319 с.

3. Калиниченко С.Г., Матвеева Н.Ю. Самоорганизация нейронных систем и модульная архитектоника головного мозга // Тихоокеанский медицинский журнал. 2010. № 4. С. 8-11.

4. Калиниченко С.Г., Матвеева Н.Ю., Мотавкин П.А. Морфофункциональная характеристика нейровазальных связей коры мозжечка // Тихоокеанский медицинский журнал. 2015. № 1. C. 26-29.

5. Apps R., Hawkes R. Cerebellar cortical organization: a one map hypothesis // Nat. Rev. Neurosci. 2009. Vol. 10, No. 9. P. 670-681.

6. Armstrong C.L., Hawkes R. Pattern formation in the cerebellar cortex // Biochem. Cell. Biol. 2000. Vol. 78. P. 551-562.

7. Barmack N.H., Yakhnitsa V. Functions of interneurons in mouse cerebellum // J. Neurosci. 2008. Vol. 28, No. 5. P. 1140-1152.

8. Bower J.M. The organization of cerebellar cortical circuitry revisited. Implication for function // Ann. N.Y. Acad. Sci. 2002. Vol. 978. P. 135-155.

9. Cerminara N.L. Cerebellar modules: individual or composite entities? // J. Neurosci. 2010. Vol. 30. P. 16065-16067.

10. Cerminara N. L., Aoki H., Loft M. [et al.]. Structural basis of cerebellar micricircuits in the rat // J. Neurosci. 2013. Vol. 33. P 16427-16442.

11. Cerminara N.L., Apps R. Behavioural significance of cerebellar modules // Cerebellum. 2013. Vol. 10. P 484-494.

12. Cohen D., Yarom Y. Cerebellar on-beam and lateral inhibition: two functionally distinct circuits // J. Neurophysiol. 2000. Vol. 83. P. 1932-1940.

13. D>Angelo E., Mazzarello P, Prestori F. [et al.]. The cerebellar network: from structure to function and dynamics // Brain Res. Rev. 2011. Vol. 66. P. 5-15.

14. Eccles J.C., Ito M., Szentagothai J. The cerebellum as a neuronal machine. NY: Springer-Verlag, 1967. 97 p.

15. Garwicz M. Micro-organisation of cerebellar modules controlling forelimb movements // Prog. Brain Res. 2000. Vol. 124. P. 187-199.

16. Glickstein M. Stratab P, Voogd J. Cerebellum: history // Neuroscience. 2009. Vol. 162. P. 549-559.

17. Hallem J.S., Thompson J.H., Gundappa-Sulur G. [et al.]. Spatial correspondence between tactile projection patterns and the distribution of the antigenic Purkinje cell markers anti-zebrin I and anti-zebrin II in the cerebellar folium crus IIA of the rat // Neuroscience. 1999. Vol. 93. P 1083-1094.

18. Hawkes R. An anatomical model of cerebellar modules // Prog. Brain. Res. 1997. Vol. 114. P 39-52.

19. Hawkes R., Gravel C. The modular cerebellum // Prog. Neurobiol. 1991. Vol. 36. P 309-327.

20. Hawkes R., Turner R.W. Compartmentation of NADPH-diaphorase activity in the mouse cerebellar cortex // J. Comp. Neurol. 1994. Vol. 346. P 499-516.

21. Ito M. Cerebellar circuitry as a neuronal machine // Prog. Neurobiol. 2006. Vol. 78. P. 272-303.

22. Jörntell H., Bengtsson F., Schonewille M. [et al.]. Cerebellar molecular layer interneurons - computational properties and roles in learning // Trends Neurosci. 2010. Vol. 33, No. 11. P. 524-532.

23. Karam S.D., Burrows R.C., Logan C. [et al.]. Eph receptors and ephrins in the developing chick cerebellum: relationship to sagittal patterning and granule cell migration // J. Neurosci. 2000. Vol. 20. P. 6488-6500.

24. Kolb F.P., Arnold G., Lerch R. [et al.]. Spatial distribution of field potential profiles in the cat cerebellar cortex evoked by peripheral and central inputs // Neuroscience. 1997. Vol. 81. P. 1155-1181.

25. Llinas R.R., Walton K.D. Cerebellum // The synaptic organization of the brain. 4th ed. / G. Shepherd (ed.). NY: Oxford University Press, 1998. P. 255-288.

26. Oberdick J., Sillitoe R.V. Cerebellar zones: history, development, and function // Cerebellum. 2011. Vol. 10, No. 3. P 301-306.

27. Ros H., Sachdev R.N., Yu Y. [et al.]. Neocortical networks entrain neuronal circuits in cerebellar cortex // J. Neurosci. 2009. Vol. 29. P. 10309-10320.

28. Sanchez M., Sillitoe R.V., Attwell PJ. [et al.]. Compartmentation of the rabbit cerebellar cortex // J. Comp. Neurol. 2002. Vol. 444. P. 159-173.

29. Sugihara I., Shinoda Y. Molecular, topographic, and functional organization of the cerebellar cortex: a study with combined aldolase C and olivocerebellar labeling // J. Neurosci. 2004. Vol. 24, No. 40. P. 8771-8785.

30. Szentagothai J. Self-organization: the basic principle of neural functions // Theor. Med. 1993. Vol. 14. P. 101-116.

31. Tom J.H. Ruigrok. Ins and Outs of Cerebellar Modules // Cerebellum. 2011. Vol. 10. P. 464-474.

32. Voogd J. The human cerebellum // J. Chem. Neuroanat. 2003. Vol. 26. P. 243-252.

33. Walther E.U., Dichgans M., Maricich S.M. [et al.]. Genomic sequences of aldolase C (Zebrin II) direct lacZ expression exclusively in non-neuronal cells of transgenic mice // Proc. Natl. Acad. Sci. USA. 1998. Vol. 95. P 2615-2620.