Figure S1. BBB versus BRB. We tested whether the results from our BRB model are also valid for the situation at the BBB by comparing ICON and brain slice image after injection. The High-permeable Tween 80 PBCA NPs, the low-permeable Tween 80-SDS PBCA NPs and Rhodamine 123 (fluorescent marker without NP as control group) showed comparable fluorescence signals between retina and brain tissue.
Enhancing cortical plasticity and brain connectivity may improve residual vision following a visual impairment. Since acetylcholine plays an important role in attention and neuronal plasticity, we explored whether potentiation of the cholinergic transmission has an effect on the visual function restoration. To this end, we evaluated for 4 weeks the effect of the acetylcholinesterase inhibitor donepezil on brightness discrimination, visually evoked potentials, and visual cortex reactivity after a bilateral and partial optic nerve crush in adult rats. Donepezil administration enhanced brightness discrimination capacity after optic nerve crush compared to nontreated animals. The visually evoked activation of the primary visual cortex was not restored, as measured by evoked potentials, but the cortical neuronal activity measured by thallium autometallography was not significantly affected four weeks after the optic nerve crush. Altogether, the results suggest a role of the cholinergic system in postlesion cortical plasticity. This finding agrees with the view that restoration of visual function may involve mechanisms beyond the area of primary damage and opens a new perspective for improving visual rehabilitation in humans.
Repetitive transorbital alternating current stimulation (rtACS) improves vision in patients with chronic visual impairments and an acute treatment increased survival of retinal neurons after optic nerve crush (ONC) in rodent models of visual system injury. However, despite this protection no functional recovery could be detected in rats, which was interpreted as evidence of “silent survivor” cells. We now analysed the mechanisms underlying this “silent survival” effect. Using in vivo microscopy of the retina we investigated the survival and morphology of fluorescent neurons before and after ONC in animals receiving rtACS or sham treatment. One week after the crush, more neurons survived in the rtACS-treated group compared to sham-treated controls. In vivo imaging further revealed that in the initial post-ONC period, rtACS induced dendritic pruning in surviving neurons. In contrast, dendrites in untreated retinae degenerated slowly after the axonal trauma and neurons died. The complete loss of visual evoked potentials supports the hypothesis that cell signalling is abolished in the surviving neurons. Despite this evidence of “silencing”, intracellular free calcium imaging showed that the cells were still viable. We propose that early after trauma, complete dendritic stripping following rtACS protects neurons from excitotoxic cell death by silencing them.
Minor
changes in the composition of poloxamer 188-modified, DEAE-dextran-stabilized
(PDD) polybutylcyanoacrylate (PBCA) nanoparticles (NPs), by altering
the physicochemical parameters (such as size or surface charge), can
substantially influence their delivery kinetics across the blood–retina
barrier (BRB) in vivo. We now investigated the physicochemical mechanisms
underlying these different behaviors of NP variations at biological
barriers and their influence on the cellular and body distribution.
Retinal whole mounts from rats injected in vivo with fluorescent PBCA
NPs were processed for retina imaging ex vivo to obtain a detailed
distribution of NPs with cellular resolution in retinal tissue. In
line with previous in vivo imaging results, NPs with a larger size
and medium surface charge accumulated more readily in brain tissue,
and they could be more easily detected in retinal ganglion cells (RGCs),
demonstrating the potential of these NPs for drug delivery into neurons.
The biodistribution of the NPs revealed a higher accumulation of small-sized
NPs in peripheral organs, which may reduce the passage of these particles
into brain tissue via a “steal effect” mechanism. Thus,
systemic interactions significantly determine the potential of NPs
to deliver markers or drugs to the central nervous system (CNS). In
this way, minor changes of NPs’ physicochemical parameters
can significantly impact their rate of brain/body biodistribution.
Future studies to elucidate mechanism of reduced toxicity of Aconitum carmichaeli when combined with Panax ginseng will guide future formula optimization.
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