Environmental enrichment extends ocular dominance plasticity into adulthood and protects from stroke-induced impairments of plasticity

This sounds exactly like what Dr. Dale Corbett was proposing in 2011. Maybe now stroke hospitals will do something about it if YOU tell them about this type of research.

Environmental enrichment extends ocular dominance plasticity into adulthood and protects from stroke-induced impairments of plasticity

1. Franziska Greifzu^a,
2. Justyna Pielecka-Fortuna^a,
3. Evgenia Kalogeraki^a,
4. Katja Krempler^b,¹,
5. Plinio D. Favaro^c,
6. Oliver M. Schlüter^c, and
7. Siegrid Löwel^a,²

Author Affiliations

1. Edited* by Michael P. Stryker, University of California, San Francisco, CA, and approved November 27, 2013 (received for review July 18, 2013)

Abstract

Ocular dominance (OD) plasticity in mouse primary visual cortex (V1) declines during postnatal development and is absent beyond postnatal day 110 if mice are raised in standard cages (SCs). An enriched environment (EE) promotes OD plasticity in adult rats. Here, we explored cellular mechanisms of EE in mouse V1 and the therapeutic potential of EE to prevent impairments of plasticity after a cortical stroke. Using in vivo optical imaging, we observed that monocular deprivation in adult EE mice (i) caused a very strong OD plasticity previously only observed in 4-wk-old animals, (ii) restored already lost OD plasticity in adult SC-raised mice, and (iii) preserved OD plasticity after a stroke in the primary somatosensory cortex. Using patch-clamp electrophysiology in vitro, we also show that (iv) local inhibition was significantly reduced in V1 slices of adult EE mice and (v) the GABA/AMPA ratio was like that in 4-wk-old SC-raised animals. These observations were corroborated by in vivo analyses showing that diazepam treatment significantly reduced the OD shift of EE mice after monocular deprivation. Taken together, EE extended the sensitive phase for OD plasticity into late adulthood, rejuvenated V1 after 4 mo of SC-rearing, and protected adult mice from stroke-induced impairments of cortical plasticity. The EE effect was mediated most likely by preserving low juvenile levels of inhibition into adulthood, which potentially promoted adaptive changes in cortical circuits.

Ocular dominance (OD) plasticity induced by monocular deprivation (MD) is one of the best studied models of experience-dependent plasticity in the mammalian cortex (1, 2). OD plasticity in primary visual cortex (V1) of C57BL/6J mice is maximal at 4 wk of age, declines after 2–3 mo, and is absent beyond postnatal day 110 (PD110) if animals are raised in standard cages (SCs) (3⇓⇓–6). In 4-wk-old mice, 4 d of MD are sufficient to induce an OD shift to the open eye; therefore, neurons in the binocular V1, which are usually dominated by the contralateral eye in rodents (3, 7), become activated more equally by both eyes (5, 8). This juvenile OD shift is predominantly mediated by a decrease in the visual cortical responses to the deprived eye (1, 9⇓–11), whereas significant OD shifts in older animals up to PD110 need 7 d of MD and are mediated primarily by increased open-eye responses in V1. Raising animals in an enriched environment (EE) gives them the opportunity of enhanced physical, social, and cognitive stimulation and influences brain physiology and behavior in many ways (12, 13). It has been shown previously that EE enhances visual system development in rats (14) and mice (15⇓–17), increases levels of the brain-derived neurotrophic factor and serotonin (18), reduces both extracellular GABA levels (18, 19) and the density of ECM perineuronal nets (PNNs) (19), and promotes OD plasticity in adult and aging rats (18⇓⇓–21). Here, we explored cellular mechanisms of EE in V1 of mice and the therapeutic potential of EE to prevent impairments of plasticity after a cortical stroke. Furthermore, we studied whether EE would prolong the sensitive phase for OD plasticity into adulthood and also restore this form of plasticity in mice that were raised in SC until PD110 (i.e., in animals that were already beyond their sensitive phase for OD plasticity). Despite pharmacological detection of in vivo GABA levels, suggesting that EE reduces intracortical inhibition, direct electrophysiological evidence is still missing. We therefore recorded GABA, AMPA, and NMDA currents in slices from EE- and SC-raised mice and also tested the efficacy of diazepam injections to abolish OD plasticity of EE mice in vivo. Finally, we studied whether raising mice in EE would protect them from lesion-induced impairments of OD plasticity. Our results show that raising mice in EE preserved OD plasticity into late adulthood rejuvenated the brain after 3 mo of SC-rearing, and protected adult mice from stroke-induced impairments of cortical plasticity. Our electrophysiological measurements and diazepam treatment indicate that the plasticity-promoting effect of EE was primarily mediated by reduced intracortical inhibition compared with SC-raised mice. These results suggest EE as a preventive intervention to enhance and preserve plasticity in adulthood and after a cortical lesion.