ผลต่างระหว่างรุ่นของ "หน้าหลัก"

For instance, Wilson and colleagues (2006) reported an general WM density of 171 NG2 cells/mm2 in the CNS. However, Levine and colleagues (1993) reported 14 NG2 cells per every 40,000 mm2 within the standard cerebellum. Such variability might reflect unique region-specific functions for NG2 cells all through the brain and spinal cord. Additional, no differences have been observed within the WMNIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author ManuscriptBrain Res. Author manuscript; available in PMC 2015 September 25.Coulibaly et al.Pageversus GM distribution of any from the OL lineage cells examined in this study, suggesting that these cells might serve functional roles in each the WM and GM.NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author ManuscriptIt is exciting to note that the density of mature OLs and TrkB cells inside the spinal cord was roughly 10 fold greater than the NG2 cell density. Barnabe-Heider et al. (2010) reported that the amount of OLs within the spinal cord increased over time, while the number of OPCs didn't. This activity could clarify the greater density of mature OLs compared with OPCs observed in the present study. 3.4. Summary and Conclusions Though TrkB nonneuronal cells in the spinal cord have been previously classified as OLs, tiny was identified concerning their distribution and/or phenotype. The outcomes with the present study reveal that the nonneuronal TrkB cells expressed Olig2, verifying that they're indeed OL lineage cells. These TrkB cells were distributed uniformly all through the white and gray matter in the adult spinal cord. The widespread distribution of TrkB cells suggests that BDNF and/or NT-4 utilization by these cells may perhaps happen throughout all regions from the adult spinal cord. Regional sources of BDNF may well originate from neurons (Lu et al., 2005), nonneuronal cells like astrocytes (Friedman et al., 1998; Dougherty et al., 2000) and/or microglia (Dougherty et al., 2000). Constant with prior findings (Horner et al., 2002; Staugaitis and Trapp, 2009), OPCs and mature OLs also showed equal distribution within the WM and GM. Interestingly, the TrkB population did not overlap completely with either OPC or OL populations. TrkB cells exhibited morphological qualities far more similar to mature OLs, and TrkB was expressed by a substantial proportion of mature OLs, even though handful of OPCs expressed detectable levels of TrkB. Only a small proportion of OPCs expressed detectable levels of TrkB, and this TrkB expressing pool of OPCs may well represent a small population of OPCs preparing for renewal or the differentiation and maturation into OLs. When the majority of OLs expressed TrkB, a subset of mature OLs didn't express TrkB, suggesting that some mature OLs minimize TrkB expression. Further, approximately 17 of TrkB cells expressed neither NG2 nor CC1. This `TrkB only' population may perhaps represent an immature stage of OL maturation that has downregulated NG2, but not yet up-regulated mature markers for instance CC1. Mature OLs were observed to type clusters with like cells inside the spinal cord, and these clusters had been extra abundant inside the GM. This cellular association suggests a communication in between OL lineage cells plus a D-Glutamic acid Endogenous Metabolite supportive glial network to neurons. Certainly, a current study demonstrated that mature OLs can provide lactate as an power source to nearby neurons (Lee et al., 2012). Approx.