| Nome |
# |
|
alpha-Synuclein Amyloids Hijack Prion Protein to Gain Cell Entry, Facilitate Cell-to-Cell Spreading and Block Prion Replication, file dd8a4bf7-e251-20a0-e053-d805fe0a8cb0
|
257
|
|
Graphene Oxide Nanosheets Reshape Synaptic Function in Cultured Brain Networks, file dd8a4bf8-0561-20a0-e053-d805fe0a8cb0
|
227
|
|
Nanostructures to Engineer 3D Neural-Interfaces: Directing Axonal Navigation toward Successful Bridging of Spinal Segments, file dd8a4bf7-936c-20a0-e053-d805fe0a8cb0
|
128
|
|
Advances in Nano Neuroscience: From Nanomaterials to Nanotools, file dd8a4bf8-5080-20a0-e053-d805fe0a8cb0
|
117
|
|
alpha-Synuclein Amyloids Hijack Prion Protein to Gain Cell Entry, Facilitate Cell-to-Cell Spreading and Block Prion Replication, file dd8a4bf7-e250-20a0-e053-d805fe0a8cb0
|
115
|
|
Graphene-Based Nanomaterials for Neuroengineering: Recent Advances and Future Prospective, file dd8a4bf8-fcce-20a0-e053-d805fe0a8cb0
|
91
|
|
Transparent carbon nanotubes promote the outgrowth of enthorino-dentate projections in lesioned organ slice cultures, file dd8a4bf8-9456-20a0-e053-d805fe0a8cb0
|
80
|
|
3D meshes of carbon nanotubes guide functional reconnection of segregated spinal explants, file dd8a4bf7-259c-20a0-e053-d805fe0a8cb0
|
68
|
|
PEDOT:PSS interfaces support the development of neuronal synaptic networks with reduced neuroglia response in vitro, file dd8a4bf7-1f25-20a0-e053-d805fe0a8cb0
|
63
|
|
Sculpting neurotransmission during synaptic development by 2D nanostructured interfaces, file dd8a4bf7-9d3d-20a0-e053-d805fe0a8cb0
|
57
|
|
Exploiting natural polysaccharides to enhance in vitro bio-constructs of primary neurons and progenitor cells, file dd8a4bf7-f52a-20a0-e053-d805fe0a8cb0
|
57
|
|
Single-layer graphene modulates neuronal communication and augments membrane ion currents, file dd8a4bf8-0c49-20a0-e053-d805fe0a8cb0
|
55
|
|
The mechanisms of humic substances self-assembly with biological molecules: The case study of the prion protein, file dd8a4bf7-e893-20a0-e053-d805fe0a8cb0
|
53
|
|
3D meshes of carbon nanotubes guide functional reconnection of segregated spinal explants, file dd8a4bf8-0717-20a0-e053-d805fe0a8cb0
|
50
|
|
Quantification of Circulating Cancer Biomarkers via Sensitive Topographic Measurements on Single Binder Nanoarrays, file dd8a4bf7-faad-20a0-e053-d805fe0a8cb0
|
43
|
|
From 2D to 3D: novel nanostructured scaffolds to investigate signalling in reconstructed neuronal networks, file dd8a4bf7-1d39-20a0-e053-d805fe0a8cb0
|
40
|
|
Adhesion to carbon nanotube conductive scaffolds forces action-potential appearance in immature rat spinal neurons, file dd8a4bf7-224a-20a0-e053-d805fe0a8cb0
|
38
|
|
Interfacing Neurons with Nanostructured Electrodes Modulates Synaptic Circuit Features, file dd8a4bf9-03bd-20a0-e053-d805fe0a8cb0
|
38
|
|
Graphene-Based Interfaces Do Not Alter Target Nerve Cells, file dd8a4bf8-d89f-20a0-e053-d805fe0a8cb0
|
37
|
|
BDNF impact on synaptic dynamics: extra or intracellular long-term release differently regulates cultured hippocampal synapses, file dd8a4bf8-a42e-20a0-e053-d805fe0a8cb0
|
36
|
|
Prion protein interaction with soil humic substances: environmental implications, file dd8a4bf7-26ec-20a0-e053-d805fe0a8cb0
|
31
|
|
Polystyrene Nanopillars with Inbuilt Carbon Nanotubes Enable Synaptic Modulation and Stimulation in Interfaced Neuronal Networks, file dd8a4bf8-fc61-20a0-e053-d805fe0a8cb0
|
30
|
|
Safety Assessment of Graphene-Based Materials: Focus on Human Health and the Environment, file dd8a4bf8-45c9-20a0-e053-d805fe0a8cb0
|
28
|
|
Atomic force microscopy based nanoassay: A new method to study α-Synuclein-dopamine bioaffinity interactions, file dd8a4bf7-4d15-20a0-e053-d805fe0a8cb0
|
27
|
|
Safety Assessment of Graphene-Based Materials: Focus on Human Health and the Environment, file dd8a4bf8-45c8-20a0-e053-d805fe0a8cb0
|
27
|
|
Single-layer graphene modulates neuronal communication and augments membrane ion currents, file dd8a4bf8-0c44-20a0-e053-d805fe0a8cb0
|
26
|
|
Functional rewiring across spinal injuries via biomimetic nanofiber scaffolds, file dd8a4bf8-c21e-20a0-e053-d805fe0a8cb0
|
25
|
|
Functional rewiring across spinal injuries via biomimetic nanofiber scaffolds, file dd8a4bf8-c109-20a0-e053-d805fe0a8cb0
|
20
|
|
TEGylated Double-Walled Carbon Nanotubes as Platforms to Engineer Neuronal Networks, file f873768b-70be-4334-834d-f5a346f89a0c
|
19
|
|
Sculpting neurotransmission during synaptic development by 2D nanostructured interfaces, file dd8a4bf7-9d3e-20a0-e053-d805fe0a8cb0
|
16
|
|
Single-layer graphene modulates neuronal communication and augments membrane ion currents, file dd8a4bf8-0ca1-20a0-e053-d805fe0a8cb0
|
16
|
|
Myoblast adhesion, proliferation and differentiation on Human Elastin-Like Polypeptide (HELP) hydrogels, file dd8a4bf8-86c5-20a0-e053-d805fe0a8cb0
|
14
|
|
Distributed interfacing by nanoscale photodiodes enables single-neuron light activation and sensory enhancement in 3D spinal explants, file cc0f2021-1d43-4f62-a7b2-a1378ccbca12
|
10
|
|
Short-term angiotensin II treatment regulates cardiac nanomechanics: Via microtubule modifications, file dd8a4bf8-fd65-20a0-e053-d805fe0a8cb0
|
10
|
|
Tuning neuronal circuit formation in 3D polymeric scaffolds by introducing graphene at the bio/material interface, file dd8a4bf8-a194-20a0-e053-d805fe0a8cb0
|
6
|
|
Safety Assessment of Graphene-Based Materials: Focus on Human Health and the Environment, file dd8a4bf8-394e-20a0-e053-d805fe0a8cb0
|
5
|
|
Transparent carbon nanotubes promote the outgrowth of enthorino-dentate projections in lesioned organ slice cultures, file dd8a4bf8-998d-20a0-e053-d805fe0a8cb0
|
5
|
|
Nanostructures to Engineer 3D Neural-Interfaces: Directing Axonal Navigation toward Successful Bridging of Spinal Segments, file dd8a4bf7-6b58-20a0-e053-d805fe0a8cb0
|
4
|
|
Nanomaterials at the neural interface, file dd8a4bf7-cf22-20a0-e053-d805fe0a8cb0
|
4
|
|
Graphene Oxide Nanosheets Reshape Synaptic Function in Cultured Brain Networks, file dd8a4bf7-2596-20a0-e053-d805fe0a8cb0
|
3
|
|
Successful Regrowth of Retinal Neurons When Cultured Interfaced to Carbon Nanotube Platforms, file dd8a4bf7-71ba-20a0-e053-d805fe0a8cb0
|
3
|
|
Mapping mechanical properties of living cells at nanoscale using intrinsic nanopipette-sample force interactions, file dd8a4bf9-0536-20a0-e053-d805fe0a8cb0
|
3
|
|
Synthetic prions and other human neurodegenerative proteinopathies, file dd8a4bf7-1a00-20a0-e053-d805fe0a8cb0
|
2
|
|
Carbon Nanotube Scaffolds Instruct Human Dendritic Cells: Modulating Immune Responses by Contacts at the Nanoscale, file dd8a4bf7-1d8b-20a0-e053-d805fe0a8cb0
|
2
|
|
Enzymatic surface hydrolysis of poly(ethylene furanoate) thin films of various crystallinities, file dd8a4bf7-f42e-20a0-e053-d805fe0a8cb0
|
2
|
|
Hybrid Interfaces Made of Nanotubes and Backbone-Altered Dipeptides Tune Neuronal Network Architecture, file dd8a4bf8-a8f2-20a0-e053-d805fe0a8cb0
|
2
|
|
Carbon nanotubes might improve neuronal performance by favouring electrical shortcuts, file dd8a4bf7-1c7e-20a0-e053-d805fe0a8cb0
|
1
|
|
Graphene-Based Interfaces Do Not Alter Target Nerve Cells, file dd8a4bf7-1f24-20a0-e053-d805fe0a8cb0
|
1
|
|
Superhydrophobic functionalization of cutinase activated poly(lactic acid) surfaces, file dd8a4bf7-f1c8-20a0-e053-d805fe0a8cb0
|
1
|
|
Enzymatic Functionalization of HMLS-Polyethylene Terephthalate Fabrics Improves the Adhesion to Rubber, file dd8a4bf7-f675-20a0-e053-d805fe0a8cb0
|
1
|
|
Carbon Nanotubes, Directly Grown on Supporting Surfaces, Improve Neuronal Activity in Hippocampal Neuronal Networks, file dd8a4bf8-97d0-20a0-e053-d805fe0a8cb0
|
1
|
|
Mutant p53 induces Golgi tubulo-vesiculation driving a prometastatic secretome, file dd8a4bf8-fc63-20a0-e053-d805fe0a8cb0
|
1
|
| Totale |
1.996 |