Ramakrishnan Kannan
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Explore the profile of Ramakrishnan Kannan including associated specialties, affiliations and a list of published articles.
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23
Citations
241
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Recent Articles
1.
Curt J, Martin P, Foronda D, Hudry B, Kannan R, Shetty S, et al.
PLoS Genet
. 2025 Jan;
21(1):e1011355.
PMID: 39804927
Hox proteins, a sub-group of the homeodomain (HD) transcription factor family, provide positional information for axial patterning in development and evolution. Hox protein functional specificity is reached, at least in...
2.
Maynard G, Kannan R, Liu J, Wang W, Lam T, Wang X, et al.
Lancet Neurol
. 2023 Jul;
22(8):672-684.
PMID: 37479373
Background: Spinal cord injury (SCI) causes neural disconnection and persistent neurological deficits, so axon sprouting and plasticity might promote recovery. Soluble Nogo-Receptor-Fc decoy (AXER-204) blocks inhibitors of axon growth and...
3.
Gogia N, Tare M, Kannan R, Singh A
Front Mol Neurosci
. 2023 Feb;
16:1134855.
PMID: 36818654
No abstract available.
4.
Narendiran S, Debnath M, Shivaram S, Kannan R, Sharma S, Christopher R, et al.
J Neurogenet
. 2022 May;
36(1):21-31.
PMID: 35499206
The Hereditary Spastic Paraplegias (HSPs) are a group of clinically and genetically heterogeneous disorders characterized by length dependent degeneration of the corticospinal tracts. Genetic data related to HSPs are limited...
5.
Sekine Y, Kannan R, Wang X, Strittmatter S
Exp Neurol
. 2022 Apr;
353:114070.
PMID: 35398339
Neural repair after traumatic spinal cord injury depends upon the restoration of neural networks via axonal sprouting and regeneration. Our previous genome wide loss-of-function screen identified Rab GTPases as playing...
6.
Blum T, Graves J, Zachman M, Polo-Garzon F, Wu Z, Kannan R, et al.
Small Methods
. 2021 Dec;
5(5):e2100035.
PMID: 34928097
Forming an ultra-thin, permeable encapsulation oxide-support layer on a metal catalyst surface is considered an effective strategy for achieving a balance between high stability and high activity in heterogenous catalysts....
7.
Lindborg J, Tran N, Chenette D, Deluca K, Foli Y, Kannan R, et al.
Cell Rep
. 2021 Mar;
34(9):108777.
PMID: 33657370
Adult mammalian central nervous system (CNS) trauma interrupts neural networks and, because axonal regeneration is minimal, neurological deficits persist. Repair via axonal growth is limited by extracellular inhibitors and cell-autonomous...
8.
Clarke A, McQueen P, Fang H, Kannan R, Wang V, McCreedy E, et al.
Mol Biol Cell
. 2020 Jan;
31(6):466-477.
PMID: 31967946
The fundamental problem in axon growth and guidance is understanding how cytoplasmic signaling modulates the cytoskeleton to produce directed growth cone motility. Live imaging of the TSM1 axon of the...
9.
Clarke A, McQueen P, Fang H, Kannan R, Wang V, McCreedy E, et al.
Mol Biol Cell
. 2020 Jan;
31(6):452-465.
PMID: 31967935
The fundamental problem in axon growth and guidance is to understand how cytoplasmic signaling modulates the cytoskeleton to produce directed growth cone motility. We here dissect this process using live...
10.
Nadella R, Chellappa A, Subramaniam A, More R, Shetty S, Prakash S, et al.
Hum Genomics
. 2019 Oct;
13(1):53.
PMID: 31640787
Background: Dysfunction in inwardly rectifying potassium channel Kir4.1 has been implicated in SeSAME syndrome, an autosomal-recessive (AR), rare, multi-systemic disorder. However, not all neurological, intellectual disability, and comorbid phenotypes in...