Restoring motor function using optogenetics and neural engraftment

Bryson, J. Barney; Machado, Carolina Barcellos; Lieberam, Ivo; Greensmith, Linda

doi:10.1016/j.copbio.2016.02.016

Cited by 22 publications

(15 citation statements)

References 50 publications

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“…The transport of biopharmaceuticals through the blood brain barrier can further be promoted through magnetic force applications in combination with magnetoliposomes (Thomsen et al, 2015 ). Adding nanomagnetic forces stimulation to neural grafts for spinal cord repair can be an alternative to optogenetic approaches (Bryson et al, 2016 ; Kilinc et al, 2016 ). Finally, the differential uptake of magnetic nanoparticle into different brain cell types can be used to either selectively target and sort specific brain cell types, or to build controlled patterns of brain cells for artificial neural tissues.…”

Section: Future Challenges and Perspectivementioning

confidence: 99%

Force-Mediating Magnetic Nanoparticles to Engineer Neuronal Cell Function

Gahl

Kunze

2018

Front. Neurosci.

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Cellular processes like membrane deformation, cell migration, and transport of organelles are sensitive to mechanical forces. Technically, these cellular processes can be manipulated through operating forces at a spatial precision in the range of nanometers up to a few micrometers through chaperoning force-mediating nanoparticles in electrical, magnetic, or optical field gradients. But which force-mediating tool is more suitable to manipulate cell migration, and which, to manipulate cell signaling? We review here the differences in forces sensation to control and engineer cellular processes inside and outside the cell, with a special focus on neuronal cells. In addition, we discuss technical details and limitations of different force-mediating approaches and highlight recent advancements of nanomagnetics in cell organization, communication, signaling, and intracellular trafficking. Finally, we give suggestions about how force-mediating nanoparticles can be used to our advantage in next-generation neurotherapeutic devices.

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Section: Future Challenges and Perspectivementioning

confidence: 99%

Force-Mediating Magnetic Nanoparticles to Engineer Neuronal Cell Function

Gahl

Kunze

2018

Front. Neurosci.

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“…This especially possible once coupled with stem cell therapy (Bryson et al, 2016). However, while optogenetics may treat these symptoms, this review does not intend to demonstrate the effect of photostimulation on the autoimmune function of the disorder.…”

Section: Evidence Of Therapeutic Potential For Multiple Sclerosis Relmentioning

confidence: 99%

“…Although beneficial for research, these methods are not viable translational strategies for human treatment. Moreover, these methods possess limitations such as not being able to specifically target cells, posing a risk to cellular components or the foreign DNA, and association with axonal pathology (Bryson et al, 2016;Mohanty & Lakshminarayananan, 2015). Due to the lack in cell specific targeting and the lack of lateralization to humans of non-viral methods, it seems viral delivery methods provide the most sensible means of creating an optogenetic treatment, especially when studied in non-human primate models.…”

Section: Current Delivery Strategies and Therapeutic Obstaclesmentioning

confidence: 99%

“…Ultimately, furthering this therapeutic tool is limited by the knowledge present for specific symptoms as well as their mechanisms (Bryson et al, 2016;Jazayeri & Remington, 2016;Mohanty & Lakshminarayananan, 2015;Mudiayi et al, 2015). Just as optogenetics may be used as a therapeutic tool, it can be utilized to understand these symptoms as it is currently used as an investigative tool (Carter & de Lecea, 2011;Mohanty & Lakshminarayananan, 2015;Mudiayi et al, 2015).…”

Section: Future Directions and Conclusionmentioning

confidence: 99%

“…Indeed, the current literature on the topic does not present any research on the translation of optogenetic treatment into any neurogenerative models expressing similar symptomology, requiring further research in this field (Ahmad, Ashraf, & Komai, 2015;Bordia, Perez, Heiss, Zhang, & Quik, 2016;Bryson, Machado, Lieberam, & Greensmith, 2016;Jazayeri & Remington, 2016). This review paper will assess the potential use of optogenetics in the development of therapies for MS related symptoms such as cognitive impairment, visual impairment, bladder/bowel dysfunction, and tremors.…”

Section: Current Delivery Strategies and Therapeutic Obstaclesmentioning

confidence: 99%

See 2 more Smart Citations

Therapeutic Potential of Optogenetic Treatment for Individuals with Multiple Sclerosis

Koussy¹,

Jadavji²

2017

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Steering Molecular Activity with Optogenetics: Recent Advances and Perspectives

Fan

Skeeters

et al. 2021

Advanced Biology

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In a transparent medium, lensbased optical microscopy could focus a coherent light beam (e.g., laser) into a tiny spot, whose dimension is comparable to the size of the wavelength of the light. The diameter of the smallest beam waist is about half the size of the wavelength, which is referred to as the diffraction limit. Thus, for visible light, the theoretical diffraction limit is between 200 and 400 nm, much smaller than the size of a single cell (Figure 1A). However, in biological tissues that significantly scatter and absorb visible light, the spatial resolution could be compromised. In multicellular organisms, light absorption limits the penetration depth. The scattering of the light by the opaque biological tissues would expand the volume of light stimulation and reduce the spatial resolution.

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Restoring motor function using optogenetics and neural engraftment

Cited by 22 publications

References 50 publications

Force-Mediating Magnetic Nanoparticles to Engineer Neuronal Cell Function

Force-Mediating Magnetic Nanoparticles to Engineer Neuronal Cell Function

Therapeutic Potential of Optogenetic Treatment for Individuals with Multiple Sclerosis

Steering Molecular Activity with Optogenetics: Recent Advances and Perspectives

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