A Theranostic Nanoprobe for Hypoxia Imaging and Photodynamic Tumor Therapy.

Hypoxia is a common feature for most malignant tumors, which was also closely related to the oxygen-dependent photodynamic therapy. Based on Förster resonance energy transfer (FRET), a smart nanoprobe (designated as H-Probe) was designed in this paper for hypoxia imaging and photodynamic tumor therapy. Due to the FRET process, H-Probe could respond to hypoxia with a significant fluorescence recovery.

Epigenetics-inspired photosensitizer modification for plasma membrane-targeted photodynamic tumor therapy.

In recent years, epigenetics has attracted great attentions in the field of biomedicine, which is used to denote the heritable changes in gene expression without any variation in DNA sequence, including DNA methylation, histone modification and so on. Inspired by it, a simple and versatile amino acids modification strategy is proposed in this paper to regulate the subcellular distribution of photosensitizer for plasma membrane targeted photodynamic therapy (PDT). Particularly, the plasma membrane anchoring ability and photo toxicity of the photosensitizer against different cell lines could be effectively manipulated at a single amino acid level.

Chimeric peptide engineered exosomes for dual-stage light guided plasma membrane and nucleus targeted photodynamic therapy.

Targeted delivery of the drug to its therapeutically active site with low immunogenicity and system toxicity is critical for optimal tumor therapy. In this paper, exosomes as naturally-derived nano-sized membrane vesicles are engineered by chimeric peptide for plasma membrane and nucleus targeted photosensitizer delivery and synergistic photodynamic therapy (PDT). Importantly, a dual-stage light strategy is adopted for precise PDT by selectively and sequentially destroying the plasma membrane and nucleus of tumor cells.

Ratiometric theranostic nanoprobe for pH imaging-guided photodynamic therapy.

An abnormal pH microenvironment results from the development of tumors, and also affects the therapeutic efficiency of anti-tumor drugs. In this work, a Förster resonance energy transfer (FRET)-based theranostic fluorescent nanoprobe was constructed for simultaneous ratiometric pH sensing and tumor-targeted photodynamic therapy. Based on the FRET process between rhodamine B and protoporphyrin IX (PpIX), the fabricated nanoprobe exhibited excellent pH responsiveness in both solutions and live cells with the ratiometric fluorescence changes.

A Self-Delivery Chimeric Peptide for Photodynamic Therapy Amplified Immunotherapy.

In this paper, a self-delivery chimeric peptide PpIX-PEG -KVPRNQDWL is designed for photodynamic therapy (PDT) amplified immunotherapy against malignant melanoma. After self-assembly into nanoparticles (designated as PPMA), this self-delivery system shows high drug loading rate, good dispersion, and stability as well as an excellent capability in producing reactive oxygen species (ROS). After cellular uptake, the ROS generated under light irradiation could induce the apoptosis and/or necrosis of tumor cells, which would subsequently stimulate the anti-tumor immune response.

Mitochondria and plasma membrane dual-targeted chimeric peptide for single-agent synergistic photodynamic therapy.

Mitochondria and cell membrane play important roles in maintaining cellular activity and stability. Here, a single-agent self-delivery chimeric peptide based nanoparticle (designated as M-ChiP) was developed for mitochondria and plasma membrane dual-targeted photodynamic tumor therapy. Without additional carrier, M-ChiP possessed high drug loading efficacy as well as the excellent ability of producing reactive oxygen species (ROS).