31 research outputs found
PEG Branched Polymer for Functionalization of Nanomaterials with Ultralong Blood Circulation
Nanomaterials have been actively pursued for biological and medical
applications in recent years. Here, we report the synthesis of several new
poly(ethylene glycol) grafted branched-polymers for functionalization of
various nanomaterials including carbon nanotubes, gold nanoparticles (NP) and
gold nanorods (NRs), affording high aqueous solubility and stability for these
materials. We synthesize different surfactant polymers based upon
poly-(g-glutamic acid) (gPGA) and poly(maleic anhydride-alt-1-octadecene)
(PMHC18). We use the abundant free carboxylic acid groups of gPGA for attaching
lipophilic species such as pyrene or phospholipid, which bind to nanomaterials
via robust physisorption. Additionally, the remaining carboxylic acids on gPGA
or the amine-reactive anhydrides of PMHC18 are then PEGylated, providing
extended hydrophilic groups, affording polymeric amphiphiles. We show that
single-walled carbon nanotubes (SWNTs), Au NPs and NRs functionalized by the
polymers exhibit high stability in aqueous solutions at different pHs, at
elevated temperatures and in serum. Morever, the polymer-coated SWNTs exhibit
remarkably long blood circulation (t1/2 22.1 h) upon intravenous injection into
mice, far exceeding the previous record of 5.4 h. The ultra-long blood
circulation time suggests greatly delayed clearance of nanomaterials by the
reticuloendothelial system (RES) of mice, a highly desired property for in vivo
applications of nanomaterials, including imaging and drug delivery
Visualizing Graphene Based Sheets by Fluorescence Quenching Microscopy
Graphene based sheets have stimulated great interest due to their superior
mechanical, electrical and thermal properties. A general visualization method
that allows quick observation of these single atomic layers would be highly
desirable as it can greatly facilitate sample evaluation and manipulation, and
provide immediate feedback to improve synthesis and processing strategies. Here
we report that graphene based sheets can be made highly visible under a
fluorescence microscope by quenching the emission from a dye coating, which can
be conveniently removed afterwards by rinsing without disrupting the sheets.
Current imaging techniques for graphene based sheets rely on the use of special
substrates. In contrast, the fluorescence quenching mechanism is no longer
limited by the types of substrates. Graphene, reduced graphene oxide, or even
graphene oxide sheets deposited on arbitrary substrates can now be readily
visualized by eye with good contrast for layer counting. Direct observation of
suspended sheets in solution was also demonstrated. The fluorescence quenching
microscopy offers unprecedented imaging flexibility and could become a general
tool for characterizing graphene based materials.Comment: J. Am. Chem. Soc., Article ASA
A functional platform for controlled subcellular distribution of carbon nanotubes
As nanoparticles can cross different cellular barriers and access different tissues, control of their uptake and cellular fate presents a functional approach that will be broadly applicable to nanoscale technologies in cell biology. Here we show that the trafficking of single-walled carbon nanotubes (SWCNTs) through various subcellular membranes of the plant cell is facilitated or inhibited by attaching a suitable functional tag and controlling medium components. This enables a unique control over the uptake and the subcellular distribution of SWCNTs and provides a key strategy to promote their cellular elimination to minimize toxicity. Our results also demonstrate that SWCNTs are involved in a carrier-mediated transport (CMT) inside cells; this is a phenomenon that scientists could use to obtain novel molecular insights into CMT, with the potential translation to advances in subcellular nanobiology