Lycium barbarum polysaccharides (LBPs) are the major polysaccharides extracted from L. barbarum, which is used in traditional Chinese medicine (TCM) for treating diseases. Studies have shown that LBPs have important biological activities, such as antioxidation, anti-aging, neuroprotection, immune regulation. LBPs inhibit oxidative stress, improve neurodegeneration and stroke-induced neural injury, increase proliferation and differentiation of neural stem cell, and promote neural regeneration. Here we have reviewed latest advances in the biomedical activities of LBPs and improved methods for the isolation, extraction, and purification of LBPs. Then, new discoveries to decrease oxidative stress and cellular apoptosis, inhibit aging progress, and improve neural repair in neurodegeneration and ischemic brain injury have been discussed in detail through in vitro cell culture and in vivo animal studies. Importantly, the molecular mechanisms of LBPs in playing neuroprotective roles are further explored. Lastly, we discuss the perspective of LBPs as biomedical compounds in TCM and modern medicine and provide the experimental and theoretical evidence to use LBPs for the treatment of aging-related neurological diseases and stroke-induced neural injuries.

Alzheimer’s disease (AD) is the most prevalent age-related neurodegenerative disease which is mainly caused by aggregated protein plaques in degenerating neurons of the brain. These aggregated protein plaques are mainly consisting of amyloid β (Aβ) fibrils and neurofibrillary tangles (NFTs) of phosphorylated tau protein. Even though the transgenic murine models can recapitulate some of the AD phenotypes, they are not the human cell models of AD. Recent breakthrough in somatic cell reprogramming made it available to use induced pluripotent stem cells (iPSCs) for patient- specific disease modeling and autologous transplantation therapy. Human iPSCs provide alternative ways to obtain specific human brain cells of AD patients to study the molecular mechanisms and therapeutic approaches for familial and sporadic forms of AD. After differentiation into neuronal cells, iPSCs have enabled the investigation of the complex aetiology and timescale over which AD develops in human brain. Here, we first go over the pathological process of and transgenic models of AD. Then we discuss the application of iPSC for disease model and cell transplantation. At last the challenges and future applications of iPSCs for AD will be summarized to propose cell-based approaches for the treatment of this devastating disorder.

Receptor tyrosine kinases mediate the extracellular signals and transmit them into the cytoplasm by activating intracellular proteins through tyrosine phosphorylation. Both Ephs and platelet-derived growth factor (PDGF) receptors (PDGFRs) have been implicated in neurogenesis, but the functional interaction between these two pathways is poorly understood. Here, we demonstrated that EphA4 directly interacts with PDGFRβ and mutually activates each other when expressed in HEK293T cells. H9-derived neural stem cells express Ephs and PDGFRs, and their proliferation is stimulated by ephrin-A1 and PDGF-BB with further augmentation by their combined application. As both EphA4 and PDGFRβ play important roles in preventing neurodegeneration and promoting neuroprotection, their interaction and transactivation might transduce the signal through the EphA4/PDGFRβ complex and augment the proliferation of neural stem cells.

Human umbilical cord blood-derived mononuclear cells (hUCB-MNCs) were reported to have neurorestorative capacity for neurological disorders such as stroke and traumatic brain injury. This study was performed to explore if hUCB-MNC transplantation plays any therapeutic effects for Parkinson’s disease (PD) in a 6-OHDA-lesioned rat model of PD. hUCB-MNCs were isolated from umbilical cord blood and administered to the striatum of the 6-OHDA-lesioned rats. The apomorphine-induced locomotive turning-overs were measured to evaluate the improvement of motor dysfunctions of the rats after administration of hUCB-MNCs. We observed that transplanted hUCB-MNCs significantly improve the motor deficits of the PD rats and that grafted hUCB-MNCs integrated to the host brains and differentiated to neurons and dopamine neurons in vivo after 16 weeks of transplantation. Our study provided evidence that transplanted hUCB-MNCs play therapeutic effects in a rat PD model by differentiating to neurons and dopamine neurons.