about
Inherent interfacial mechanical gradients in 3D hydrogels influence tumor cell behaviorsMimicking white matter tract topography using core-shell electrospun nanofibers to examine migration of malignant brain tumors.Glioblastoma behaviors in three-dimensional collagen-hyaluronan composite hydrogels.Toward 3D biomimetic models to understand the behavior of glioblastoma multiforme cellsHydrogel-electrospun fiber mat composite coatings for neural prostheses.In vivo capture and label-free detection of early metastatic cells.Secretome identification of immune cell factors mediating metastatic cell homing.Extracellular matrix mediators of metastatic cell colonization characterized using scaffold mimics of the pre-metastatic nicheGlioma-astrocyte interactions on white matter tract-mimetic aligned electrospun nanofibers.Biomimetic strategies to recapitulate organ specific microenvironments for studying breast cancer metastasis.Polylysine-modified PEG-based hydrogels to enhance the neuro-electrode interface.Enhanced Survival with Implantable Scaffolds That Capture Metastatic Breast Cancer Cells In Vivo.Synergistic effect of eribulin and CDK inhibition for the treatment of triple negative breast cancer.The influence of matrix stiffness on the behavior of brain metastatic breast cancer cells in a biomimetic hyaluronic acid hydrogel platform.Biomimetic models to examine microenvironmental regulation of glioblastoma stem cellsBioengineered models to study tumor dormancyBiomaterial Scaffolds as Pre-metastatic Niche Mimics Systemically Alter the Primary Tumor and Tumor MicroenvironmentAn in vitro hyaluronic acid hydrogel based platform to model dormancy in brain metastatic breast cancer cellsMicroporous scaffolds loaded with immunomodulatory lentivirus to study the contribution of immune cell populations to tumor cell recruitment in vivoRole of Surface Chemistry in Mediating the Uptake of Ultrasmall Iron Oxide Nanoparticles by Cancer CellsThree-dimensional biomimetic hyaluronic acid hydrogels to investigate glioblastoma stem cell behaviorsThree dimensional culture models to study drug resistance in breast cancer
P50
Q27303927-479AD396-46B6-4138-9E85-50C20AE9E3E0Q30582618-E974F8F2-7785-49D2-BE90-CB967457CA81Q30620741-634DB182-F65F-44EB-8FBB-911D34A5C876Q34025911-49440377-FDB9-4EBD-826B-E4074F91EE78Q34701296-D2B981C1-12FF-4FF1-BC46-8FDE0710FD35Q36040727-A7A33BCF-C814-4158-BAD5-48DF0A3EB30FQ36346184-A4C25CCC-6666-4DAD-B9A6-501A210DB244Q36649724-8ED5C862-D54F-4AB6-86E4-89C4B67C3F1AQ38863325-94C9155B-AE72-4207-B733-6694D5E1FA4CQ39260571-2F0FB6CB-4898-423E-9680-3788E58C5B1CQ39690163-C27CBBBC-F67E-4018-B7B3-F6F8CA398E33Q41122321-52148DAD-1FE9-4169-88E8-79022F18966BQ46592179-E3980D6C-6C22-49E8-A8D1-89F2370B30FDQ53450028-F8ECD3F0-59CB-4CCE-A2CC-27D065A26142Q57584287-F816D244-0571-4961-B5D3-EC2E5195102DQ60912605-9CFB786D-854E-4265-8BF8-6709E450E01BQ64332786-B8A138D7-AEA6-44FC-9575-C6B914753AE6Q89972964-80807B41-84D8-47C1-80ED-7FDF8AA3CC8CQ90212845-A8C322D4-92F1-4428-B950-F61F603A7AEFQ90267814-87EAD720-12F8-48B1-813F-F6D1DC890B53Q91136088-8A8ADF3F-F054-4CE4-BD11-ABEA8966C2D7Q91984655-68581117-C94B-4CF6-B442-105838D855E7
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Shreyas Rao
@ast
Shreyas Rao
@en
Shreyas Rao
@es
Shreyas Rao
@nl
Shreyas Rao
@sl
type
label
Shreyas Rao
@ast
Shreyas Rao
@en
Shreyas Rao
@es
Shreyas Rao
@nl
Shreyas Rao
@sl
prefLabel
Shreyas Rao
@ast
Shreyas Rao
@en
Shreyas Rao
@es
Shreyas Rao
@nl
Shreyas Rao
@sl
P108
P106
P1153
36768758200
P31
P496
0000-0001-7649-0171