Developing a Tooth Organ Culture Model for Dental and Periodontal Regeneration Research.

In this study we have realized the need for an organ culture tooth model to simulate the tooth structure especially the tooth attachment apparatus. The importance of such a model is to open avenues for investigating regeneration of the complex tooth and tooth attachment tissues and to reduce the need for experimental animals in investigating dental materials and treatments in the future. The aim of this study was to develop a porcine tooth organ culture model and a novel bioreactor suitable for future studies of periodontal regeneration, including application of appropriate physiological loading.

Early life selective knockdown of the TrkB receptor and maternal separation modulates adult stress phenotype.

Brain Derived Neurotrophic Factor (BDNF) is a neurotrophin that has been implicated in mood and anxiety disorders and is upregulated by antidepressants. It has marked effects on synaptic and extra-synaptic plasticity through tropomyosin receptor kinase B (TrkB). Importantly, early life stressors that affect BDNF production are known to predispose individuals towards the later development of depression or anxiety disorders.

Non-destructive monitoring of viability in an ex vivo organ culture model of osteochondral tissue.

Organ culture is an increasingly important tool in research, with advantages over monolayer cell culture due to the inherent natural environment of tissues. Successful organ cultures must retain cell viability. The aim of this study was to produce viable and non-viable osteochondral organ cultures, to assess the accumulation of soluble markers in the conditioned medium for predicting tissue viability.

The life span of ganglionic glia in murine sensory ganglia estimated by uptake of bromodeoxyuridine.

Studies of ganglionic glia turnover in the sensory nervous system have implications for understanding nervous system maintenance and repair. These glial cells of the sensory ganglia in the peripheral nervous system (PNS) comprise satellite cells (SCs) and, to a lesser extent, Schwann cells. SCs proliferate in response to trauma such as axotomy; however, the half-life of these glial cells under normal circumstances has not been estimated.

Satellite cell proliferation in murine sensory ganglia in response to scarification of the skin.

Satellite cells (SCs) ensheathe neuronal cell bodies of sensory ganglia and provide mechanical and metabolic support for neurons. In mice, grossly detrimental stimuli such as nerve crush or cut, or explant culture of ganglia induce proliferation of SCs. It is unknown whether SC proliferation occurs in response to the less severe trauma that might commonly occur in a physiological situation.