Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease characterized by progressive muscle wasting and limb paralysis. This neurodegenerative condition results from the gradual destruction of motor neurons, the nerve cells that control muscles.

Past neuroscience studies have identified a TAR DNA-binding protein that plays a key role in ALS, known as TDP-43. This protein, which generally regulates RNA processing (i.e., how genetic information is managed inside cells), was found to abnormally accumulate in the axons (i.e., nerve fibers) of patients diagnosed with ALS.

Researchers at Tel Aviv University, Sheba Medical Center and other institutes carried out a study aimed at further exploring the mechanisms that underpin this local aggregation of TDP-43 in axons.

Cadoni et al. show that expression of the bacterial sonogenetic ion channel MscL(G22S) allows focused ultrasound (FUS) neuromodulation of the mouse visual cortex. They even provide evidence for possible induction of a visual percept in mice via this approach, though much more work is needed to make this into a useful visual restoration method. It should be noted that some of the FUS frequencies used in Cadoni et al.’s experiments were quite high (15 MHz), so a surgically implanted cranial window was needed. I personally think that it would be better to focus on frequencies that can be employed in a transcranial fashion to minimize invasiveness. That said, there is still merit to moderately invasive methods as seen here. #sonogenetics [ https://www.nature.com/articles/s41565-023-01359-6](https://www.nature.com/articles/s41565-023-01359-6)

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Sonogenetics provides neuron-specific activation at high spatiotemporal resolution ex vivo in retina and in vivo deep in the visual cortex using the AAV gene delivery of a mechanosensitive ion channel and low-intensity ultrasound stimulations.

From patient to genetics research pioneer — christian maugee — phd candidate, university of florida.

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Christian Maugee is a PhD Candidate at the University of Florida, in Genetics and Genomics (http://www.vulpelab.net/graduate-and-undergrad-students.html where his research explores how gene expression differs in the hearts of individuals with Friedrich’s Ataxia (FA), a rare, progressive neurodegenerative disease. His work could lead to new insights into the cardiac complications that can be associated with FA and how to potential treat them better.

Christian’s dissertation work is focused on identifying gene modulators of the transcriptional phenotype of FA in human induced pluripotent stem cells differentiated into cardiomyocytes (hPSC-CMs). He accomplishes this through use of a novel method: Perturb-seq — a CRISPR screen coupled with single cell RNA sequencing (scRNA-seq) readout.

Christian is driven by much more than academic curiosity, as he brings a unique and deeply human perspective to his work as someone living with FA. He doesn’t just study the challenges faced by those with disabilities; he lives them. His work is not only informed by data and theory, but by resilience, authenticity, and a commitment to making research more inclusive and impactful.

In the lab, Christian loves mentoring, and outside of the lab he loves fundraising and raising awareness for FA, mainly through FARA (https://www.curefa.org/) and MDA (https://www.mda.org/disease/friedreic…).