Hyaluronic Acid Nanoparticles Based on a Conjugated Oligomer Photosensitizer: Target-Specific Two-Photon Imaging, Redox-Sensitive Drug Delivery, and Synergistic Chemo-Photodynamic Therapy.

Self-assembled hyaluronic acid (HA) nanoparticles have been extensively investigated as anticancer therapeutic agents due to the biocompatibility, biodegradability, and active targeting characteristics of HA. However, many HA nanoparticles are restricted to the applications in drug delivery for chemotherapy or lack effective imaging agents. Hence, we developed the camptothecin (CPT)-loaded HA-SS-BFVPBT nanoparticles (HSBNPs) as a multifunctional platform for two-photon imaging and synergistic chemo-photodynamic therapy at the same time. A novel conjugated oligomer photosensitizer, BFVPBT, which was conjugated onto HA through the redox-responsive disulfide linkage (SS), could not only provide a hydrophobic domain for the formation of nanoparticles and drug entrapment but also act as a two-photon photosensitizer that can be directly excited and simultaneously used in two-photon imaging and photodynamic therapy (PDT). HeLa cells overexpressing the HA receptor (CD44) were used for in vitro studies, which proved the specific cellular uptake of CPT-loaded HSBNPs and excellent two-photon PDT/chemotherapy synergistic effect. The nanoparticles have also been shown to realize tumor-targeting in vivo imaging in HeLa-tumor-bearing mice. Moreover, the fluorescence of CPT-loaded HSBNPs could be activated due to the degradation by the reductive glutathione (GSH) and overexpressed hyaluronidases (Hyal-1) in cancer cells, and the intracellular drug release rate was quickened, thus improving the probability of precise cancer diagnosis and therapy. Accordingly, this HSBNPs system is also anticipated to be a precise nanocarrier for other imaging and therapeutic agents besides CPT, offering a promising new avenue for imaging-guided efficient cancer therapy.

Solvent- and pH-induced self-assembly of cationic meta-linked poly(phenylene ethynylene): effects of helix formation on amplified fluorescence quenching and Förster resonance energy transfer.

We reported here the synthesis and characterization of a novel water-soluble, meta-linked poly(phenylene ethynylene) (m-PPE-NEt(2)Me(+)) featuring quaternized side groups. We studied the solvent-induced self-assembly of m-PPE-NEt(2)Me(+) in MeOH/H(2)O solvent mixtures by using UV-vis absorption and fluorescence spectroscopies. The results showed that the polymer folded into a helical conformation and that the extent of helical folding increased with the volume % water in the solvent. This cationic polymer also exhibited unique pH-induced helix formation, which was attributed to the partial neutralization of quaternized side groups at high pH and the meta-links in the main chain of the polymer. Studies on the fluorescence quenching of m-PPE-NEt(2)Me(+) by anthraquinone-2,6-disulfonate (AQS) and Fe(CN)(6)(4-), two small-molecule anionic quenchers with different typical structures, revealed more efficient quenching of helical conformation by AQS than by Fe(CN)(6)(4-). We proposed that the two quenchers most likely interacted with the polymer helix in two different modes; that was, AQS featuring large planar aromatic ring could intercalate within adjacent π-stacked phenylene ethynylene units in the polymer helix, whereas Fe(CN)(6)(4-) mainly bound to the periphery of polymer helix through ion-pair formation. Finally, the results of FRET from the helical polymer to the fluorescein (C*)-labeled polyanions, ssDNA-C* (ssDNA: single-stranded DNA) and dsDNA-C* (dsDNA: double-stranded DNA) also suggested two different modes of interactions. As compared with the FRET to dsDNA-C*, the FRET to ssDNA-C* was slightly more efficient, which was believed to arise from the additional binding of ssDNA-C* with the polymer via intercalation of its exposed hydrophobic bases into the π stack of adjacent phenylene ethynylene units in the polymer helix.

Tuning backbones and side-chains of cationic conjugated polymers for optical signal amplification of fluorescent DNA detection.

Three cationic conjugated polymers (CCPs) exhibiting different backbone geometries and charge densities were used to investigate how their conjugated backbone and side chain properties, together with the transitions of DNA amphiphilic properties, interplay in the CCP/DNA-C* (DNA-C*: fluorophore-labeled DNA) complexes to influence the optical signal amplification of fluorescent DNA detection based on Förster resonance energy transfer (FRET). By examining the FRET efficiencies to dsDNA-C* (dsDNA: double-stranded DNA) and ssDNA-C* (ssDNA: single-stranded DNA) for each CCP, twisted conjugated backbones and higher charge densities were proved to facilitate electrostatic attraction in CCP/dsDNA-C* complexes, and induced improved sensitivity to DNA hybridization. Especially, by using the CCP with twisted conjugated backbone and the highest charge density, a more than 7-fold higher efficiency of FRET to dsDNA-C* was found than to ssDNA-C*, indicating a high signal amplification for discriminating between dsDNA and ssDNA. By contrast, linear conjugated backbones and lower charge density were demonstrated to favor hydrophobic interactions in CCP/ssDNA-C* complexes. These findings provided guidelines for the design of novel sensitive CCP, which can be useful to recognize many other important DNA activities involving transitions of DNA amphiphilic properties like DNA hybridization, such as specific DNA binding with ions, some secondary or tertiary structural changes of DNA, and so forth.