Ute Hochgeschwender
Overview
Explore the profile of Ute Hochgeschwender including associated specialties, affiliations and a list of published articles.
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63
Citations
979
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Recent Articles
1.
Lee C, Lin J, Lin S, Chang C, Wu Y, Bewick G, et al.
Sci Adv
. 2025 Jan;
11(5):eabc5219.
PMID: 39888990
Proprioceptors are primary mechanosensory neurons to monitor the status of muscle contraction and/or body position (). Although proprioceptors are known as non-nociceptive mechanoreceptors, they also express the pro-nociceptive acid-sensing ion...
2.
Ikefuama E, Slaviero A, Schalau R, Gott M, Tree M, Dunbar G, et al.
bioRxiv
. 2024 Aug;
PMID: 39091860
Early stages of Huntington's disease (HD) before the onset of motor and cognitive symptoms are characterized by imbalanced excitatory and inhibitory output from the cortex to striatal and subcortical structures....
3.
Hochgeschwender U, Campbell R, Mizuno H
Neurophotonics
. 2024 Jul;
11(2):024200.
PMID: 38948889
The editorial introduces the Special Section on Molecular Neurophotonics.
4.
Slaviero A, Gorantla N, Simkins J, Crespo E, Ikefuama E, Tree M, et al.
Neurophotonics
. 2024 Apr;
11(2):024208.
PMID: 38559366
Significance: Luminopsins (LMOs) are bioluminescent-optogenetic tools with a luciferase fused to an opsin that allow bimodal control of neurons by providing both optogenetic and chemogenetic access. Determining which design features...
5.
Bjorefeldt A, Murphy J, Crespo E, Lambert G, Prakash M, Ikefuama E, et al.
Neurophotonics
. 2024 Mar;
11(2):021005.
PMID: 38450294
Significance: Bioluminescent optogenetics (BL-OG) offers a unique and powerful approach to manipulate neural activity both opto- and chemogenetically using a single actuator molecule (a LuMinOpsin, LMO). Aim: To further enhance...
6.
Slaviero A, Gorantla N, Simkins J, Crespo E, Ikefuama E, Tree M, et al.
bioRxiv
. 2023 Dec;
PMID: 38045286
Significance: Luminopsins (LMOs) are bioluminescent-optogenetic tools with a luciferase fused to an opsin that allow bimodal control of neurons by providing both optogenetic and chemogenetic access. Determining which design features...
7.
Petersen E, Lapan A, Castellanos Franco E, Fillion A, Crespo E, Lambert G, et al.
ACS Synth Biol
. 2023 Jul;
12(8):2301-2309.
PMID: 37450884
Genetically encoded optical sensors and advancements in microscopy instrumentation and techniques have revolutionized the scientific toolbox available for probing complex biological processes such as release of specific neurotransmitters. Most genetically...
8.
Crespo E, Pal A, Prakash M, Silvagnoli A, Zaidi Z, Gomez-Ramirez M, et al.
bioRxiv
. 2023 Jul;
PMID: 37425742
We developed a platform that utilizes a calcium-dependent luciferase to convert neuronal activity into activation of light sensing domains within the same cell. The platform is based on a luciferase...
9.
Bjorefeldt A, Murphy J, Crespo E, Lambert G, Prakash M, Ikefuama E, et al.
bioRxiv
. 2023 Jul;
PMID: 37425735
Significance: Bioluminescent optogenetics (BL-OG) offers a unique and powerful approach to manipulate neural activity both opto- and chemogenetically using a single actuator molecule (a LuMinOpsin, LMO). Aim: To further enhance...
10.
Lambert G, Crespo E, Murphy J, Boassa D, Luong S, Celinskis D, et al.
bioRxiv
. 2023 Jul;
PMID: 37425712
Ca plays many critical roles in cell physiology and biochemistry, leading researchers to develop a number of fluorescent small molecule dyes and genetically encodable probes that optically report changes in...