Yiting Xu

Gold@Polymer Nanostructures with Tunable Permeability Shells for Selective Catalysis

National Natural Science Foundation of China [50873082, 50903067]; Scientific and Technical Project of Fujian Province of China [2009J1009, 2010H6021]

A Simple Dual-pH Responsive Prodrug-Based Polymeric Micelles for Drug Delivery

To precisely deliver drug molecules at a targeted site and in a controllable manner, there has been great interest in designing a synergistical drug delivery system that can achieve both surface charge-conversion and controlled release of a drug in response to different stimuli. Here we outline a simple method to construct an intelligent drug carrier, which can respond to two different pH values, therefore achieving charge conversion and chemical-bond-cleavage-induced drug release in a stepwise fashion. This drug carrier comes from the self-assembly of a block copolymer-DOX conjugate synthesized through a Schiff base reaction between poly(2-(diisopropylamino)ethyl methacrylate-b-poly(4-formylphenyl methacrylate-co-polyethylene glycol monomethyl ether methacrylate) (PDPA-b-P(FPMA-co-OEGMA)) and DOX. The surface charge of the BCP-DOX micelles reversed from negative to positive when encountering a weakly acidic environment due to the protonation of PDPA segments. In vitro cellular uptake measurement shows that the cellular uptake and internalization of the BCP-DOX micelles can be significantly enhanced at pH ∼ 6.5. Moreover, this drug carrier exhibits a pH-dependent drug release owing to the cleavage of the imine bond at pH < 5.5. With this dual-pH responsive feature, these micelles may have the ability to precisely deliver DOX to the cancer cells.

CuO based inorganic-organic hybrid nanowires: a new type of highly sensitive humidity sensor

The organic surfactant template method has been widely used for the preparation of CuO nanorods, nanotubes and nanowires. However, the surfactants in this system have no effect on the properties of the final products because they are flushed away. In this work, we used this method to synthesize a novel type of inorganic-organic hybrid nanowire via the hybridization between CuO and amphiphilic oligomer octadecyl, polyethylene glycol di-butenetrioate (O-B-EG-B). Here O-B-EG-B, as a structure director, was not flushed away but remained in the prepared hybrid nanowires because it was bound around CuO or entrapped in interior CuO. The hybrid nanowires showed CuO cores and P(O-B-EG-B) shells when the concentration of O-B-EG-B was 0.4 mg ml(-1), but exhibited P(O-B-EG-B) cores and CuO shells when the concentration of O-B-EG-B was 4.0 mg ml(-1). We found that the hybrid nanowires with P(O-B-EG-B) cores and CuO shells could sense a slight change in the relative humidity (RH) and respond by rapidly changing their conductivity. The resistance changed by about two orders of magnitude within the humidity range from 5% to 83.8%. Moreover, a humidity sensor based on this type of nanowire not only showed long-term stability but also exhibited excellent reversibility to moisture changes in air.

Preparation, characterization, and antibacterial activity studies of silver-loaded poly(styrene-co-acrylic acid) nanocomposites

A simple method for preparing a new type of stable antibacterial agent was presented. Monodisperse poly(styrene-co-acrylic acid) (PSA) nanospheres, serving as matrices, were synthesized via soap-free emulsion polymerization. Field-emission scanning electron microscopy micrographs indicated that PSA nanospheres have interesting surface microstructures and well-controlled particle size distributions. Silver-loaded poly(styrene-co-acrylic acid) (PSA/Ag-NPs) nanocomposites were prepared in situ through interfacial reduction of silver nitrate with sodium borohydride, and further characterized by transmission electron microscopy and X-ray diffraction. Their effects on antibacterial activity including inhibition zone, minimum inhibitory concentration (MIC), minimum bactericidal concentration (MBC), and bactericidal kinetics were evaluated. In the tests, PSA/Ag-NPs nanocomposites showed excellent antibacterial activity against both gram-positive Staphylococcus aureus and gram-negative Escherichia coli. These nanocomposites are considered to have potential application in antibacterial coatings on biomedical devices to reduce nosocomial infection rates.

Colloidosomes constructed by the seamless connection of nanoparticles: a mobile and recyclable strategy to intelligent capsules

Colloidosomes constructed by the self-assembly of nanoparticles (NPs) on liquid–liquid interfaces have been demonstrated to be useful in many fields. However, the interspaces between NPs on the surface of colloidosomes barricade their application in small molecule encapsulation. Herein, fabrication of a new type of colloidosome built by the seamless connection of NPs via simply heating and quenching a type of core–shell structured NPs (CSNPs) aqueous system using oil as a template, is presented. These colloidosomes have a hollow structure and exhibit efficient small molecule encapsulation. More importantly, the colloidosomes can dissociate into single NPs and release the small target molecules encapsulated in interior of the colloidosomes at a temperature higher than the melting point of the CSNP shell. It is also shown that the dissociation temperature of colloidosomes can be controlled by simply adjusting the length of the PEG chains in the CSNP shell, which implies that these intelligent capsules have attractive application prospects in controlled drug release.

Synthesis of walnut-like hierarchical structure with superhydrophobic and conductive properties

Walnut-like structures made up of a polyaniline (PANI) nanofiber network and polystyrene (PS) microspheres are successfully fabricated by a novel approach, “competitive adsorption–restricted polymerization”. In the reaction system, PS microspheres are simultaneously encapsulated by cationic surfactant and aniline hydrochloride. Just this cationic surfactant molecule affects the nucleation model and second growth of PANI via electrostatic interactions and steric hindrance, which accounts for the formation of a PANI nanofiber network coating on the PS surface. The size, ordering and amount of PANI nanofibers on the three-dimensional surface can be particularly controlled by altering a variety of synthetic conditions, such as the amount of cationic surfactant, temperature and concentration. A superhydrophobic and conductive surface is obtained by drop-casting a suspension of these walnut-like PS/PANI particles onto a substrate.

Morphology tailoring and temperature sensitivity control of waist cross-linked micelles and evaluation of their application as intelligent drug carriers

A novel type of waist cross-linked micelle (WCM) was developed as an intelligent drug carrier via the self-assembly guiding free radical polymerization of an amphiphilic oligomer: octadecyl, polyethylene glycol butenedioates (O–B–EGs). By changing the concentration of O–B–EG reaction solution, WCMs with monolayer, compound and vesicle-like morphologies were obtained. These WCMs showed controllable temperature responsive properties. DLS and UV-vis analyses indicate that the critical temperatures at which WCMs show an abrupt change in particle size evidently increases with the increase in the molecular weight of the PEG chains. Direct switching of the release of pyrene in WCMs is also realized by a slight change of temperature. Pyrene is released rapidly at the temperatures around the critical temperature of the WCMs, but a further increase in temperature shuts down the release of pyrene. More importantly, these WCMs exhibit reversible and rapid pyrene releasing-absorbing behavior. We suggest that these excellent properties endow WCMs with great potential in drug encapsulation and controlled release

Waist cross-linked micelles synthesized viaself-assembly guiding radical polymerization

Amphiphilic micelles with waist cross-linked structure exhibit both core–shell reversing behavior and thermal sensitivity.

Heterogeneous silver-polyaniline nanocomposites with tunable morphology and controllable catalytic properties.

This paper introduces not only a simple hydrothermal route to silver-polyaniline (Ag-PANI) nanocomposites with controllable morphology, but also a type of catalyst possessing tunable and switchable catalytic capability. Ag-PANI Janus nanoparticles (NPs) and Ag@PANI core-shell NPs have been constructed successfully at different hydrothermal temperatures. The diameter of both Ag and PANI hemispheres of Janus NPs, as well as the PANI shell thickness of core-shell NPs, was finely tuned via adjustment of the feed ratio. We also gained a deeper insight into the functionalities of PANI components in the catalytic capability of the heterogeneous catalysts, choosing catalytic reductions of nitrobenzene (NB) and 4-nitrophenol (4-NP) as model reactions. Our results showed that the catalytic capability of the nanocomposites was dependent on the PANI morphology and hydrophobicity. The PANI shell coating on Ag NPs can concentrate the lipophilic NB, thus leading to an enhanced catalytic capability of Ag@PANI core-shell NPs. However, this enhanced catalytic capability was not observed for Ag-PANI Janus NPs when catalytically reducing NB. More importantly, the catalytic capability of the core-shell NPs in the reduction of hydrophilic 4-NP is switchable by varying the PANI shell from an undoped to a doped state.

Platinum-nanoparticle-supported core--shell polymer nanospheres with unexpected water stability and facile further modification.

Core-shell nanospheres (CSNSs) with hydrophobic cores and hydrophilic shells were fabricated via a simple mini-emulsion polymerization for the stabilization of platinum nanoparticles (Pt-NPs). The CSNSs showed extremely high loading capacity of Pt-NPs (the largest loading amount of the Pt-NPs was about 49.2 wt%). Importantly, the Pt-NPs/CSNSs nanocomposites had unexpected stability in aqueous solution. DLS results revealed that the CSNSs loaded with Pt-NPs exhibited almost no aggregation after standing for a long time . However, the Pt-NPs immobilized on the CSNSs were not straitlaced: they could transport and redistribute between CSNSs freely when the environmental temperature was higher than the melting point of the CSNS shell. Owing to their excellent stability in aqueous solution, the surface of the Pt-NPs/CSNSs nanocomposites could be further decorated easily. For example, polyaniline (PANI)-coated Pt-NPs/CSNSs, nickel (Ni)-coated Pt-NPs/CSNSs and PANI/Pt-NPs dual-layer hollow nanospheres were facilely fabricated from the Pt-NPs/CSNS nanocomposites.