Semi-automated counting of axon regeneration in poly(lactide co-glycolide) spinal cord bridges.

BACKGROUND: Spinal cord injury (SCI) is a debilitating event with multiple mechanisms of degeneration leading to life-long paralysis. Biomaterial strategies, including bridges that span the injury and provide a pathway to reconnect severed regions of the spinal cord, can promote partial restoration of motor function following SCI. Axon growth through the bridge is essential to characterizing regeneration, as recovery can occur via other mechanisms such as plasticity. Quantitative analysis of axons by manual counting of histological sections can be slow, which can limit the number of bridge designs evaluated. In this study, we report a semi-automated process to resolve axon numbers in histological sections, which allows for efficient analysis of large data sets. NEW METHOD: Axon numbers were estimated in SCI cross-sections from animals implanted with poly(lactide co-glycolide) (PLG) bridges with multiple channels for guiding axons. Immunofluorescence images of histological sections were filtered using a Hessian-based approach prior to threshold detection to improve the signal-to-noise ratio and filter out background staining associated with PLG polymer. RESULTS: Semi-automated counting successfully recapitulated average axon densities and myelination in a blinded PLG bridge implantation study. COMPARISON WITH EXISTING METHODS: Axon counts obtained with the semi-automated technique correlated well with manual axon counts from blinded independent observers across sections with a wide range of total axons. CONCLUSIONS: This semi-automated detection of Hessian-filtered axons provides an accurate and significantly faster alternative to manual counting of axons for quantitative analysis of regeneration following SCI.

Anti-muscarinic adjunct therapy accelerates functional human oligodendrocyte repair.

Therapeutic repair of myelin disorders may be limited by the relatively slow rate of human oligodendrocyte differentiation. To identify appropriate pharmacological targets with which to accelerate differentiation of human oligodendrocyte progenitors (hOPCs) directly, we used CD140a/O4-based FACS of human forebrain and microarray to hOPC-specific receptors. Among these, we identified CHRM3, a M3R muscarinic acetylcholine receptor, as being restricted to oligodendrocyte-biased CD140a(+)O4(+) cells. Muscarinic agonist treatment of hOPCs resulted in a specific and dose-dependent blockade of oligodendrocyte commitment. Conversely, when hOPCs were cocultured with human neurons, M3R antagonist treatment stimulated oligodendrocytic differentiation. Systemic treatment with solifenacin, an FDA-approved muscarinic receptor antagonist, increased oligodendrocyte differentiation of transplanted hOPCs in hypomyelinated shiverer/rag2 brain. Importantly, solifenacin treatment of engrafted animals reduced auditory brainstem response interpeak latency, indicative of increased conduction velocity and thereby enhanced functional repair. Therefore, solifenacin and other selective muscarinic antagonists represent new adjunct approaches to accelerate repair by engrafted human progenitors.

Histone deacetylase activity is required for human oligodendrocyte progenitor differentiation.

The molecular mechanisms controlling human oligodendrocyte development are poorly characterized. Microarray analysis of human oligodendrocyte progenitor cells (OPCs) and immature oligodendrocytes revealed that specific-class I histone deacetylase (HDAC) target genes were actively repressed during oligodendrocyte commitment. Although epigenetic regulation of oligodendrocyte differentiation has been established in rodent development, the role of HDACs in human OPCs remains undefined. We used HDAC inhibitors (HDACi) trichostatin A (TSA) and sodium butyrate to determine the importance of HDAC activity in human primary OPC differentiation. Treatment with either drug resulted in significant dose-dependent inhibition of O4(+) oligodendrocyte cell differentiation, reduction of oligodendrocyte morphological maturation, and downregulation of myelin basic protein mRNA. High dose TSA treatment was also associated with reduction in OPC proliferation. HDACi treatment prevented downregulation of SOX2, ID4, and TCF7L2 mRNAs but did not regulate HES5, suggesting that targets of HDAC repression may differ between species. These results predict that HDACi treatment would impair proliferation and differentiation by parenchymal oligodendrocyte progenitors, and thereby degrade their potential for endogenous repair in human demyelinating disease. © 2012 Wiley Periodicals, Inc.