Mechanoporation is a potential indicator of tissue strain and subsequent degeneration following experimental traumatic brain injury.

Background: An increases in plasma membrane permeability is part of the acute pathology of traumatic brain injury and may be a function of excessive membrane force. This membrane damage, or mechanoporation, allows non-specific flux of ions and other molecules across the plasma membrane, and may ultimately lead to cell death. The relationships among tissue stress and strain, membrane permeability, and subsequent cell degeneration, however, are not fully understood.

Mesenchymal stromal SB623 cell implantation mitigates nigrostriatal dopaminergic damage in a mouse model of Parkinson's disease.

Regenerative medicine for the treatment of motor features in Parkinson's disease (PD) is a promising therapeutic option. Donor cells can simultaneously address multiple pathological mechanisms while responding to the needs of the host tissue. Previous studies have demonstrated that mesenchymal stromal cells (MSCs) promote recovery using various animal models of PD.

Comparing the angiogenic potency of naïve marrow stromal cells and Notch-transfected marrow stromal cells.

Background: Angiogenesis is a critical part of the endogenous repair process in brain injury and disease, and requires at least two sequential steps. First, angiogenic sprouting of endothelial cells occurs, which entails the initial proliferation of endothelial cells and remodeling of the surrounding extracellular matrix. Second, vessel stabilization is necessary to prevent vascular regression, which relies on vascular smooth muscle recruitment to surround the young vessels.

Comparing the immunosuppressive potency of naïve marrow stromal cells and Notch-transfected marrow stromal cells.

Background: SB623 cells are expanded from marrow stromal cells (MSCs) transfected with a Notch intracellular domain (NICD)-expressing plasmid. In stroke-induced animals, these cells reduce infarct size and promote functional recovery. SB623 cells resemble the parental MSCs with respect to morphology and cell surface markers despite having been in extended culture.

Stem cell survival and functional outcome after traumatic brain injury is dependent on transplant timing and location.

Purpose: Recent work indicates that transplanted neural stem cells (NSCs) can survive, migrate to the injury site, and facilitate recovery from traumatic brain injury (TBI). The present study manipulated timing and location of NSC transplants following controlled cortical impact injury (CCI) in mice to determine optimal transplant conditions.

Methods: In Experiment 1 (timing), NSCs (E14.

Human mesenchymal stromal cells and their derivative, SB623 cells, rescue neural cells via trophic support following in vitro ischemia.

Cell transplantation is a promising treatment strategy for many neurological disorders, including stroke, which can target multiple therapeutic mechanisms in a sustained fashion. We investigated the ability of human mesenchymal stromal cells (MSCs) and MSC-derived SB623 cells to rescue neural cells via trophic support following an in vitro stroke model. Following oxygen glucose deprivation, cortical neurons or hippocampal slices were cocultured with either MSCs or SB623 cells separated by a semiporous membrane (prohibits cell-cell contact) or with MSC- or SB623 cell-conditioned medium.

Extracellular matrix produced by bone marrow stromal cells and by their derivative, SB623 cells, supports neural cell growth.

Several studies have shown the benefits of transplanting bone marrow-derived multipotent mesenchymal stromal cells (MSC) into neurodegenerative lesions of the central nervous system, despite a low engraftment rate and the poor persistence of grafts. It is known that the extracellular matrix (ECM) modulates neuritogenesis and glial growth, but little is known about effects of MSC-derived ECM on neural cells. In this study, we demonstrate in vitro that the ECM produced by MSC can support neural cell attachment and growth.

Laminin and fibronectin scaffolds enhance neural stem cell transplantation into the injured brain.

Cell transplantation offers the potential to treat central nervous system injuries, largely because multiple mechanisms can be targeted in a sustained fashion. It is crucial that cells are transplanted into an environment that is favourable for extended survival and integration within the host tissue. Given the success of using fetal tissue grafts for traumatic brain injury, it may be beneficial to mimic key aspects of these grafts (e.

In vitro neural injury model for optimization of tissue-engineered constructs.

Stem cell transplantation is a promising approach for the treatment of traumatic brain injury, although the therapeutic benefits are limited by a high degree of donor cell death. Tissue engineering is a strategy to improve donor cell survival by providing structural and adhesive support. However, optimization prior to clinical implementation requires expensive and time-consuming in vivo studies.

Plasma fibronectin is neuroprotective following traumatic brain injury.

Promotion of repair and regeneration following traumatic brain injury remains a challenging clinical problem. While significant efforts have been made to reduce inhibitory extracellular matrix expression following central nervous system injury, much less attention has been given to the role of endogenous reparative matrix proteins, such as fibronectin. Traumatic brain injury leads to increased levels of plasma-derived fibronectin in the brain tissue, though the specific function of this protein following neurotrauma was unknown.

Role of plasma fibronectin in the foreign body response to biomaterials.

Host responses to biomaterials control the biological performance of implanted medical devices. Upon implantation, synthetic materials adsorb biomolecules, which trigger an inflammatory cascade comprising coagulation, leukocyte recruitment/adhesion, and foreign body reaction. The foreign body reaction and ensuing fibrous encapsulation severely limit the in vivo performance of numerous biomedical devices.

Fibronectin and laminin increase in the mouse brain after controlled cortical impact injury.

The complex environment of the traumatically injured brain exhibits aspects of inhibition and ongoing cell death together with attempts at repair and regeneration. Elucidating these events and exploiting those factors involved in endogenous repair and regeneration may aid in developing more effective treatments for traumatic brain injury. Two extracellular matrix proteins critical to neural development--fibronectin and laminin--may also play a protective or reparative role in the injury response.