New opportunities: the use of nanotechnologies to manipulate and track stem cells.
about
The effect of surface nanometre-scale morphology on protein adsorptionStem Cell Tracking with Nanoparticles for Regenerative Medicine Purposes: An OverviewNanotechnology in neurology: Genesis, current status, and future prospectsMagnetic resonance imaging of transplanted stem cell fate in strokeNanoparticle-based monitoring of cell therapy.Efficient generation of virus-free iPS cells using liposomal magnetofectionConcise review: carbon nanotechnology: perspectives in stem cell researchComparative in vitro study on magnetic iron oxide nanoparticles for MRI tracking of adipose tissue-derived progenitor cellsPre-clinical characterization of tissue engineering constructs for bone and cartilage regeneration.Commercial nanoparticles for stem cell labeling and tracking.Real-time optical imaging using quantum dot and related nanocrystals.The use of gadolinium-carbon nanostructures to magnetically enhance stem cell retention for cellular cardiomyoplasty.NanoScript: a nanoparticle-based artificial transcription factor for effective gene regulation.g-force induced giant efficiency of nanoparticles internalization into living cellsHarmonic nanoparticles for regenerative research.Three-dimensional culture of human embryonic stem cell derived hepatic endoderm and its role in bioartificial liver constructionTargeting of embryonic stem cells by peptide-conjugated quantum dots.Bioinspired materials for controlling stem cell fate.Stem cell tracking by nanotechnologiesNon-invasive imaging of human embryonic stem cells.Synergistically enhanced osteogenic differentiation of human mesenchymal stem cells by culture on nanostructured surfaces with induction mediaNoninvasive near-infrared live imaging of human adult mesenchymal stem cells transplanted in a rodent model of Parkinson's disease.Gadonanotubes as magnetic nanolabels for stem cell detection.Nanomaterials for Engineering Stem Cell Responses.High-throughput screening of substrate chemistry for embryonic stem cell attachment, expansion, and maintaining pluripotency.Nanostructured surfaces of dental implantsFunction of mesenchymal stem cells following loading of gold nanotracersCharacteristics of 2 Different Commercially Available Implants with or without Nanotopography.Polarization-controlled differentiation of human neural stem cells using synergistic cues from the patterns of carbon nanotube monolayer coating.Cell-surface sensors for real-time probing of cellular environments.Nanofibrous substrates support colony formation and maintain stemness of human embryonic stem cells.Successful deep anterior lamellar keratoplasty following multiple failed limbal transplantations for chronic ocular burns.Cationic liposome-mediated CXCR4 gene delivery into hematopoietic stem/progenitor cells: implications for clinical transplantation and gene therapy.Interactions of 1D- and 2D-layered inorganic nanoparticles with fibroblasts and human mesenchymal stem cells.Orthopaedic applications of nanoparticle-based stem cell therapiesBiofunctionalization of a titanium surface with a nano-sawtooth structure regulates the behavior of rat bone marrow mesenchymal stem cells.Human mesenchymal stem cells labelled with dye-loaded amorphous silica nanoparticles: long-term biosafety, stemness preservation and traceability in the beating heart.In vivo near-infrared imaging for the tracking of systemically delivered mesenchymal stem cells: tropism for brain tumors and biodistributionSustained Delivery Growth Factors with Polyethyleneimine-Modified Nanoparticles Promote Embryonic Stem Cells Differentiation and Liver Regeneration.Advanced correlative light/electron microscopy: current methods and new developments using Tokuyasu cryosections.
P2860
Q21136246-762EFCFE-C0B1-452D-AE56-2D0C10A67D90Q26770087-824FD995-2586-46C4-861D-63B9FB96E88DQ26771772-D4322085-29B1-4C55-B54C-026E3A597308Q26828783-0B9CE9FA-8AEB-411E-A6F1-378195C4365EQ27000646-C5D38EC0-7B3B-4BD0-938C-3317451B8A79Q27317250-1F74A6D8-B72C-4244-BC21-6C65CEC601ECQ28383608-520F95FC-3DF3-45EC-8982-C3CD9EB439EAQ28543135-FC9A6AEF-048D-47E1-9B71-8CE41EE6768DQ30389472-AA337237-1AA9-44A3-A8EA-72ED59D47DAAQ30450859-ED4632FE-99E1-4F1A-967E-211F2304BC40Q30524195-8616FEFD-B8F4-44C4-A77C-21A3CBDD08C8Q30567453-DAD1E274-FC3A-4ECF-A1AB-F7D459B6BAF9Q30587595-4C7A6F21-594E-4B93-A2CE-0EF29B8B3105Q30669061-8FB0AC91-76F9-44A3-8A5B-1AA40234F100Q30822925-AA325225-D865-42E9-965C-ED0512943BF6Q33652334-C30F2408-FB85-4C37-BD07-E185B25731ABQ33658930-48855996-494B-45CF-8F91-8947ACA5C7BBQ33733340-3DA4A725-3776-4A13-9502-CB62C14F7BD1Q33848165-33FA3A2C-A66D-4F3C-9027-8C2801CF662FQ34050057-B5F73E44-5265-4358-9130-7DE265D9FCE2Q34066708-4F8D7623-6D1E-434A-BC8C-1CE9C56D3162Q34159147-CEF17443-9413-4761-BA15-B51263B6977DQ34293041-05BBA9A9-D1D1-46A0-B578-7B4455B76EF6Q34477893-A3AE55C4-00ED-4CC3-A8C1-9DA50DDCD2E3Q34512111-C38E3ADA-B532-4433-80E6-D917730E89ADQ34647541-090F1D5B-BB65-4DC8-9407-D231589BB91EQ34788253-D08F4718-3A1C-4A2B-9825-E48502A4E410Q35040567-7D434B0A-D7F7-42C7-9F44-B8AD9B8E3098Q35074874-CD4A30D7-4949-46D0-8D6C-EBB1C8665DB8Q35185609-270EFE00-7D8E-49DB-91C4-DAE02200D7C9Q35893322-7BD7522A-855F-4AFF-8237-852149F02524Q35979892-93207269-7516-458B-89A5-C3557876B1A2Q36036499-F149F8C4-D320-48EF-BC23-45088C65451EQ36076777-8B164B51-5E51-4C53-A329-D34EF0890538Q36084837-87DAC5D2-2B1F-4737-9E1E-B903E5BFB712Q36173069-ABE9A928-996C-449E-A548-BA3622B717A7Q36224187-EBFD7EEF-ED63-456C-9385-1E4AE9AE0DDDQ36402844-A1984E4D-3568-4BD5-ADCF-6286124D05E9Q37352321-E1D878D7-FCA1-4E9A-B18F-9B98D344E2BFQ37422961-CE6D3A8A-6BB1-4595-86B7-E64E5A2266BA
P2860
New opportunities: the use of nanotechnologies to manipulate and track stem cells.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on August 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
New opportunities: the use of nanotechnologies to manipulate and track stem cells.
@en
New opportunities: the use of nanotechnologies to manipulate and track stem cells.
@nl
type
label
New opportunities: the use of nanotechnologies to manipulate and track stem cells.
@en
New opportunities: the use of nanotechnologies to manipulate and track stem cells.
@nl
prefLabel
New opportunities: the use of nanotechnologies to manipulate and track stem cells.
@en
New opportunities: the use of nanotechnologies to manipulate and track stem cells.
@nl
P2093
P1433
P1476
New opportunities: the use of nanotechnologies to manipulate and track stem cells
@en
P2093
Jeffrey M Karp
Luis Nobre
Robert Langer
P304
P356
10.1016/J.STEM.2008.07.020
P407
P577
2008-08-01T00:00:00Z