Mahlet Mersha scite author profile

Mahlet Mersha

2Publications

13Citation Statements Received

153Citation Statements Given

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146

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Johns Hopkins University

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Enhanced Spontaneous Motor Recovery After Stroke in Mice Treated With Cerebrolysin

DeBoer

Hubbard

Mersha

et al. 2021

Neurorehabil Neural Repair

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Background Motor recovery after stroke in humans and in rodent models is time sensitive. Recovery in patients is a result of biological spontaneous recovery via endogenous repair mechanisms and is likely improved by enhancing the synaptic plasticity required for endogenous repair. Cerebrolysin is a polypeptide preparation known to enhance neuroplasticity and may improve recovery in patients. In mice, we tested the hypothesis that Cerebrolysin can act poststroke to enhance both spontaneous and training-associated motor recovery. Methods Mice were trained to perform a skilled prehension task. We then induced a photothrombotic stroke in the caudal forelimb area, after which we retrained animals on the prehension task in the presence or absence of Cerebrolysin after a 2-day or 8-day delay. Mice received daily intraperitoneal Cerebrolysin or saline injections starting poststroke day 1 or poststroke day 7. Results Prior studies showed that poststroke recovery of prehension can occur if animals receive rehabilitative training during an early sensitive period but is incomplete if rehabilitative training is delayed. In contrast, we show complete recovery of prehension, despite a delay in rehabilitative training, when mice receive daily Cerebrolysin administration starting on poststroke day 1 or on poststroke day 8. When Cerebrolysin is given on poststroke day 1, recovery occurred even in the absence of training. Stroke volumes were similar across groups. Conclusions Poststroke Cerebrolysin administration leads to recovery of motor function independent of rehabilitative training without a protective effect on stroke volume. This is one of the first demonstrations of training-independent motor recovery in rodent stroke models.

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In Vivo Formation and Tracking of π-Peptide Nanostructures

Dibble

DeBoer

Mersha³

et al. 2022

ACS Appl. Mater. Interfaces

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The photophysics associated with the self-assembly of π-peptide molecules into 1-D nanostructures has been wellestablished, thus revealing the creation of nanoscale electronic conduits in aqueous media. Such materials have therapeutic potential in many biomedical applications. In this work, we report the in vivo deployment of these π-peptide nanostructures in brain tissue using photothrombotic stroke as a model application. A test peptide was used for brain injections, and the nanostructures formed were visualized with electron microscopy. A new peptide bearing a low-energy fluorescence dye was prepared to facilitate direct visualization of π-peptide localization in the brain cavity by way of fluorescence microscopy. This work demonstrates feasibility for in vivo application of π-peptide nanostructures toward pressing biomedical challenges.

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Mahlet Mersha

Enhanced Spontaneous Motor Recovery After Stroke in Mice Treated With Cerebrolysin

In Vivo Formation and Tracking of π-Peptide Nanostructures

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