5-Bromo-2'-deoxyuridine (BrdU) is a marker that is widely used to label S-phase cells in neurobiological research in most common doses 50 or 100 mg/kg per single intraperitoneal (i.p.) injection. However, the important data regarding its pharmacokinetics in rodents are still missing. The aim of our study was to investigate the BrdU level in serum after a single i.p. injection to adult rats (doses: 50 or 100 mg/kg) and adult mice (50 mg/kg). The animals were killed at selected time-points after the BrdU injection, and proliferating tumour cells (cell lines HCT-116 and HL-60) were co-cultivated with isolated blood sera. BrdU incorporated in the DNA of the S-phase tumour cells was stained with an anti-BrdU antibody and analysed using flow cytometry. In rats, the efficacies of BrdU labelling of S-phase cells in both in vitro and in vivo conditions were compared in the 50 and 100 mg/kg groups. According to our results, BrdU was in saturated concentration to label almost all S-phase cells for 60 min in both doses and was detectable in blood serum until 120 min after the single i.p. injection. However, the 100 mg/kg dose of BrdU did not provide a prolonged staining period to offset the potentially higher toxicity in comparison with the 50 mg/kg dose. In mice, due to their faster metabolism, the concentration of BrdU in blood serum was sufficient to label the whole population of S-phase cells for only 15 min after the i.p. injection, then dropped rapidly.
A drug delivery system based on mesoporous particles MCM-41 was post-synthetically modified by photo-sensitive ligand, methyl-(2E)-3-(4-(triethoxysilyl)-propoxyphenyl)-2-propenoate (CA) and the pores of MCM-41 particles were loaded with Naproxen sodium salt (NAP). The CA was used as a photoactive molecule that can undergo a reversible photo-dimerization by [2π + 2π] cycloaddition when irradiated with UV light of specific wavelengths. Thus, it has a function of gate-keeper that is responsible for opening/closing the pores and minimizing premature release of NAP. The physicochemical properties of the prepared system were studied by infrared spectroscopy (IR), nitrogen adsorption measurements, thermogravimetric analysis (TGA), scanning transmission electron microscopy (STEM) and energy dispersive X-ray spectroscopy (EDX). The mechanism of the opening/closing pores was confirmed by UV measurements. In vitro and in vivo drug release experiments and the concentration of released NAP was determined by UV spectroscopy and high-performance liquid chromatography (HPLC). In vivo drug release in the blood circulatory system of rats has demonstrated the effective photo-cleavage reaction of CA molecules after UV-light stimulation. The localization and morphological changes of the particles were studied in the blood and liver of rats at different time intervals. The particles in the blood have been shown to retain their original rod-like shape, and the particles in the liver have been hydrolysed, which has resulted in spherical shape with a reduced size.
Cerebrospinal fluid contacting neurons (CSF‐cNs) represent a specific class of neurons located in close vicinity of brain ventricles and central canal. In contrast with knowledge gained from other vertebrate species, we found that vast majority of CSF‐cNs in the spinal cord of C57Bl/6N mice is located in ectopic distal ventral position. However, we found that small number of ectopic CSF‐cNs is present also in spinal cord of other investigated experimental mice strains (C57Bl/6J, Balb/C) and mammalian species (Wistar rats, New Zealand White rabbits). Similarly, as the proximal populations, ectopic CSF‐cNs retain PKD2L1‐immunoreactivity and synaptic contacts with other neurons. On the other side, they show rather multipolar morphology lacking thick dendrite contacting central canal lumen. Ectopic CSF‐cNs in the spinal cord of C57Bl/6N mice emerge during whole period devoted to production of CSF‐cNs and reach their ventral destinations during first postnatal weeks. In order to identify major gene, whose impairment could trigger translocation of CSF‐cNs outside the central canal area, we took advantage of close consanguinity of C57Bl/6J substrain with normal CSF‐cN distribution and C57Bl/6N substrain with majority of CSF‐cNs in ectopic position. Employing in silico analyses, we ranked polymorphisms in C57Bl/6N substrain and selected genes Crb1, Cyfip2, Adamts12, Plk1, and Herpud2 as the most probable candidates, whose product dysfunction might be responsible for the ectopic distribution of CSF‐cNs. Furthermore, segregation analysis of F2 progeny of parental C57Bl/6N and Balb/C mice revealed that polymorphic loci of Crb1 and Cyfip2 underlie the ectopic position of CSF‐cNs in the spinal cord of C57Bl/6N mice.
Two waves of oligodendrogenesis in the ventricular zone of the spinal cord (SC-VZ) during rat development, which take place between embryonic days 14 and 18 (E14-E18) and E20-E21, have been described. In the VZ of the brain, unlike the SC-VZ, a third wave of oligodendrogenesis occurs during the first weeks of postnatal development. Using immunofluorescence staining of intact rat SC tissue, we noticed the presence of small numbers of Olig2(+) /Sox-10(+) cells inside the lining of the central canal (CC) during postnatal development and adulthood. Olig2(+) /Sox-10(+) cells appeared inside the lining of the CC shortly after birth, and their number reached a maximum of approximately 0.65 ± 0.14 cell/40-μm section during the second postnatal week. After the latter development, the number of Olig2(+) /Sox-10(+) cells decreased to 0.21 ± 0.07 (P36) and 0.18 ± 0.1 cell/section (P120). At P21, Olig2(+) /Sox-10(+) cells inside the CC lining started to express other oligodendroglial markers such as CNPase, RIP, and APC. Olig2(+) /Sox-10(+) cells usually did not proliferate inside the CC lining and were only rarely found to be immunoreactive against oligodendrocyte progenitor markers such as NG2 or PDGFRα. Using 5-bromo-2-deoxyuridine administration at P2, P11, P22, or P120-P125, we revealed that these cells arose in the CC lining during postnatal development and adulthood. Our findings confirmed that the CC lining is the source of a small number of cells with an oligodendroglial phenotype during postnatal development and adulthood in the SC of intact rats.
Neural precursors originating in the subventricular zone (SVZ), the largest neurogenic region of the adult brain, migrate several millimeters along a restricted migratory pathway, the rostral migratory stream (RMS), toward the olfactory bulb (OB), where they differentiate into interneurons and integrate into the local neuronal circuits. Migration of SVZ-derived neuroblasts in the adult brain differs in many aspects from that in the embryonic period. Unlike in that period, postnatally-generated neuroblasts in the SVZ are able to divide during migration along the RMS, as well as they migrate independently of radial glia. The homophilic mode of migration, i.e., using each other to move, is typical for neuroblast movement in the RMS. In addition, it has recently been demonstrated that specifically-arranged blood vessels navigate SVZ-derived neuroblasts to the OB and provide signals which promote migration. Here we review the development of vasculature in the presumptive neurogenic region of the rodent brain during the embryonic period as well as the development of the vascular scaffold guiding neuroblast migration in the postnatal period, and the significance of blood vessel reorganization during the early postnatal period for proper migration of RMS neuroblasts in adulthood.
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