Test, rinse, repeat: A review of carryover effects in rodent behavioral assays.

Behavioral phenotyping has been gaining prominence due to the increased use of transgenic animal models of neurological disorders. Repeated testing in the same cohort of animals can reduce the overall number of animals used and is desired especially when animal numbers are difficult to obtain as well as for studies involving within-subject design such as drug treatments or aging. This review aims to provide researchers with a comprehensive overview of the carryover effects when subjecting the same set of animals to the same behavioral test. We have focused on three behavioral domains of testing: anxiety, cognition and depression. Based on a review of the literature and our own experiences as a neurobehavioral core facility, we have found that manipulating inter-test interval, environmental contextual cues and stimuli can mitigate the carryover effects to a large extent, although there are certain tests that still show strong residual effects. In addition, the effects of strain on carryover effects from repeated testing are also discussed in this review.

Role of NMDA Receptors in Adult Neurogenesis and Normal Development of the Dentate Gyrus.

The NMDA receptors are a type of glutamate receptors, which is involved in neuronal function, plasticity and development in the mammalian brain. However, how the NMDA receptors contribute to adult neurogenesis and development of the dentate gyrus is unclear. In this study, we investigate this question by examining a region-specific knock-out mouse line that lacks the NR1 gene, which encodes the essential subunit of the NMDA receptors, in granule cells of the dentate gyrus (DG-NR1KO mice). We found that the survival of newly-generated granule cells, cell proliferation and the size of the granule cell layer are significantly reduced in the dorsal dentate gyrus of adult DG-NR1KO mice. Our results also show a significant reduction in the number of immature neurons and in the volume of the granule cell layer, starting from three weeks of postnatal age. DG-NR1KO mice also showed impairment in the expression of an immediate early gene, Arc, and behavior during the novelty-suppressed feeding and open field test. These results suggest that the NMDA receptors in granule cells have a role in adult neurogenesis in the adult brain and contributes to the normal development of the dentate gyrus.

Biofunctional scaffolds with high packing density of aligned electrospun fibers support neural regeneration.

Neurons of the central nervous system do not regenerate spontaneously after injury. As such, biofunctional tissue scaffolds have been explored to provide a growth-promoting environment to enhance neural regeneration. In this regard, aligned electrospun fibers have proven invaluable for regeneration by offering guidance for axons to cross the injury site. However, a high fiber density could potentially limit axonal ingrowth into the scaffold. Here, we explore which fiber density provides the optimal environment for neurons to regenerate. By changing fiber electrospinning time, we generated scaffolds with different fiber densities and implanted these in a rat model of spinal cord injury (SCI). We found that neurons were able to grow efficiently into scaffolds with high fiber density, even if the gaps between fiber bundles were very small (<1 µm). Scaffolds with high fiber density showed good host-implant integration. Cell infiltration was not affected by fiber density. Efficient blood vessel ingrowth likely requires larger gaps between fibers or faster degrading fibers. We conclude that scaffolds with high fiber densities, and thus a large number of small gaps in between fiber bundles, provide the preferred environment for nerve regeneration after SCI.