Summary
Intraventricular blood vessels and choroidal-like cells were studied using scanning electron microscopy and correlative light microscopy. The intraventricular blood vessels were covered on their ependymal surface with a layer of cells essentially identical to the ependyma of the choroid plexus in the gerbil. Similar choroidal-like cells were seen either singly or in clusters associated with the cerebrospinal fluid-contacting pinealocytes of the suprapineal recess. Processes of the cerebrospinal fluid-contacting pinealocytes were seen extending to and making contact with the choroidal-like cells. The intraventricular blood vessels appeared to be derived from the choroid plexus, and typically took one of three courses in and around the surface of the deep pineal: (1) the vessels or their equivalent were located in the suprapineal recess with no indication of penetration into the substance of the deep pineal; (2) the vessels coursed from the suprapineal recess around the anterior surface of the habenular commissure to enter the ventral surface of the deep pineal; or (3) the vessels entered the parenchyma of the deep pineal from its dorsal surface and could be seen coursing through the substance of the gland. The close association between the choroidal-like cells and the intraventricular blood vessels with the deep pineal gland add morphological support for the possibility of interaction between the cerebrospinal fluid, or perhaps the choroid plexus, and the deep pineal gland.
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References
Allen DJ, Persky B, Low FN (1978) Some regional variations in ventricular lining material in laboratory mammals and man. SEM, 1978, vol II, pp 45–50
Braak H (1967) Elektronenmikroskopische Untersuchungen an Catecholaminkernen im Hypothalamus vom Goldfisch (Carassius auratus). Z Zellforsch 83:398–415
Decker JF, Quay WB (1982) Stimulatory effects of melatonin on ependymal epithelium of choroid plexuses in Golden Hamsters. J Neural Transm 55:53–67
Delahunt B, Trotter WD, Samarasinghe DD (1975) The morphology of the pineal recess of the brush-tailed possum (Trichosurus vulpecula). Proc Univ Otago Med Sch 53:63–64
Garcia JM, Alvarez-Uria M (1986) Intraventricular blood vessels of the hypothalamus of Salmo gairdneri and Gambusia affinis. Anat Rec 214:76–81
Hedlund L, Lischko MM, Rollag MD, Niswender GD (1977) Melatonin: Daily cycle in plasma and cerebrospinal fluid in calves. Science 18:686–687
Hewing M (1978) A liquor contacting area in the pineal recess of the golden hamster (Mesocricetus auratus). Anat Embryol 153:295–304
Hewing M (1980) Cerebrospinal fluid-contacting area in the pineal recess of the vole (Microtus agretis), guinea pig (Cavia cobaya), and rhesus monkey (Macaca mulatta). Cell Tissue Res 209:473–484
Hewing M (1982) Pinealocytes contacting the cerebrospinal fluid of the suprapineal recess in the Mongolian gerbil (Merione unguiculatus). Cell Tissue Res 222:177–185
Knight BK, Hayes MMM, Symington RB (1974) An anatomical study of the pineal body of the vervet monkey (Cercopithecus aethiops). S Afr J Med Sci 39:133–142
Krapp C (1978) The ependyma on the pineal of the guinea pig (Cavia cobaya). A scanning electron microscopic investigation. Anat Embryol 152:217–222
Quay WB (1970) Pineal structure and composition in the orangutan (Pongo pygmaeus). Anat Rec 168:93–104
Quay WB (1983) Actions of the pineal gland and melatonin on the secretion of cerebrospinal fluid. In: Axelrod J, Fraschini F, Velo GP (eds) The pineal gland and its endocrine role. Plenum Press, New York, pp 349–360
Reppert SM, Coleman RJ, Heath HW, Keutmann HT (1982) Circadian properties of vasopressin and melatonin rhythms in cat cerebrospinal fluid. Am J Physiol 243:E489-E498
Reppert SM, Perlow MJ, Tamarkin L, Klein DC (1979) A diurnal melatonin rhythm in primate cerebrospinal fluid. Endocrinology 104:295–301
Rollag MD, Morgan RJ, Niswender GD (1978) Route of melatonin secretion in sheep. Endocrinology 102:1–8
Samarasinghe D, Delahunt B (1980) The ependyma of the saccular pineal gland in the non-eutherian mammal Trichosurus vulpecula. A scanning electron microscopic study. Cell Tissue Res 213:417–432
Scott DE, Kozlowski GP, Sheridan MN (1974) Scanning electron microscopy in the ultrastructural analysis of the mammalian cerebral ventricular system. Int Rev Cytol 37:349–388
Sheridan MN, Reiter RJ, Jacobs JJ (1969) An interesting anatomical relationship between the hamster pineal gland and the ventricular system of the brain. J Endocrinol 45:131–132
Vollrath L (1979) Comparative morphology of the vertebrate pineal complex. Prog Brain Res 52:25–38
Welsh MG (1983) CSF-contacting pinealocytes in the pineal recess of the Mongolian gerbil: A correlative scanning and transmission electron microscope study. Am J Anat 166:483–493
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Welsh, M.G. Intraventricular blood vessels associated with the deep pineal gland of the Mongolian gerbil, Meriones unguiculatus . Cell Tissue Res. 249, 587–592 (1987). https://doi.org/10.1007/BF00217330
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DOI: https://doi.org/10.1007/BF00217330