Heparin-based self-assembled nanoparticles for photodynamic therapy

Current Limitations and Recent Progress in Nanomedicine for Clinically Available Photodynamic Therapy

Photodynamic therapy (PDT) using oxygen, light, and photosensitizers has been receiving great attention, because it has potential for making up for the weakness of the existing therapies such as surgery, radiation therapy, and chemotherapy. It has been mainly used to treat cancer, and clinical tests for second-generation photosensitizers with improved physicochemical properties, pharmacokinetic profiles, or singlet oxygen quantum yield have been conducted. Progress is also being made in cancer theranostics by using fluorescent signals generated by photosensitizers. In order to obtain the effective cytotoxic effects on the target cells and prevent off-target side effects, photosensitizers need to be localized to the target tissue. The use of nanocarriers combined with photosensitizers can enhance accumulation of photosensitizers in the tumor site, owing to preferential extravasation of nanoparticles into the tumor vasculature by the enhanced permeability and retention effect. Self-assembly of amphiphilic polymers provide good loading efficiency and sustained release of hydrophobic photosensitizers. In addition, prodrug nanomedicines for PDT can be activated by stimuli in the tumor site. In this review, we introduce current limitations and recent progress in nanomedicine for PDT and discuss the expected future direction of research.

Overviews on the cellular uptake mechanism of polysaccharide colloidal nanoparticles

Nanoparticulate drug/gene carriers have gained much attention in the past decades because of their versatile and tunable properties. However, efficacy of the therapeutic agents can be further enhanced using naturally occurring materials-based nanoparticles. Polysaccharides are an emerging class of biopolymers; therefore, they are generally considered to be safe, non-toxic, biocompatible and biodegradable. Considering that the target of nanoparticle-based therapeutic strategies is localization of biomedical agents in subcellular compartments, a detailed understanding of the cellular mechanism involved in the uptake of polysaccharide-based nanoparticles is essential for safe and efficient therapeutic applications. Uptake of the nanoparticles by the cellular systems occurs with a process known as endocytosis and is influenced by the physicochemical characteristics of nanoparticles such as size, shape and surface chemistry as well as the employed experimental conditions. In this study, we highlight the main endocytosis mechanisms responsible for the cellular uptake of polysaccharide nanoparticles containing drug/gene.

Synthesis and characterization of bioreducible heparin-polyethyleneimine nanogels: application as imaging-guided photosensitizer delivery vehicle in photodynamic therapy

HPC nanogels possess bright blue fluorescence which eliminates the use of additional probing agents in image-guided drug delivery. The results showed that disulfide crosslinked HPC nanogels are promising vehicles for stimulated photosensitizer delivery in advanced PDT.

Polysaccharide-based micelles for drug delivery

Delivery of hydrophobic molecules and proteins has been an issue due to poor bioavailability following administration. Thus, micelle carrier systems are being investigated to improve drug solubility and stability. Due to problems with toxicity and immunogenicity, natural polysaccharides are being explored as substitutes for synthetic polymers in the development of new micelle systems. By grafting hydrophobic moieties to the polysaccharide backbone, self-assembled micelles can be readily formed in aqueous solution. Many polysaccharides also possess inherent bioactivity that can facilitate mucoadhesion, enhanced targeting of specific tissues, and a reduction in the inflammatory response. Furthermore, the hydrophilic nature of some polysaccharides can be exploited to enhance circulatory stability. This review will highlight the advantages of polysaccharide use in the development of drug delivery systems and will provide an overview of the polysaccharide-based micelles that have been developed to date.

Self-assembled liposomal nanoparticles in photodynamic therapy

Photodynamic therapy (PDT) employs the combination of non-toxic photosensitizers (PS) together with harmless visible light of the appropriate wavelength to produce reactive oxygen species that kill unwanted cells. Because many PS are hydrophobic molecules prone to aggregation, numerous drug delivery vehicles have been tested to solubilize these molecules, render them biocompatible and enhance the ease of administration after intravenous injection. The recent rise in nanotechnology has markedly expanded the range of these nanoparticulate delivery vehicles beyond the well-established liposomes and micelles. Self-assembled nanoparticles are formed by judicious choice of monomer building blocks that spontaneously form a well-oriented 3-dimensional structure that incorporates the PS when subjected to the appropriate conditions. This self-assembly process is governed by a subtle interplay of forces on the molecular level. This review will cover the state of the art in the preparation and use of self-assembled liposomal nanoparticles within the context of PDT.

Heparin-folate-retinoic acid bioconjugates for targeted delivery of hydrophobic photosensitizers

Amphiphilic heparin-retinoic acid (HR) and heparin-folate-retinoic acid bioconjugates (HFR) were synthesized by chemical conjugation of a hydrophobic anticancer agent all-trans-retinoic acid (RA) and a targeting ligand, folic acid (FA), to the high molecular weight heparin backbone. The HR and HFR bioconjugates had a high RA content (22%, w/w) and could self-assemble into nanoparticles with efficient encapsulation of a hydrophobic photosensitizer, pheophorbide a (PhA). The HFR bioconjugate demonstrated higher PhA loading content and loading efficiency compared to HR bioconjugate. The PhA-loaded HR and HFR nanoparticles had an average diameter of about 70 nm, a negatively charged surface, a sustained release pattern and self-quenching effect in a buffered solution. Furthermore, the cellular uptake of PhA-loaded HFR nanoparticles in folate receptor-positive HeLa cells was higher than that of PhA-loaded HR nanoparticles. Upon irradiation, HFR nanoparticles selectively enhanced the phototoxicity of PhA in HeLa cells while the dark-toxicity of the nanoparticles was minimal without light treatment. HFR nanoparticles also demonstrated targeted anti-cancer effect, improving the cytotoxicity of RA in HeLa cells compared to HR nanoparticles at RA concentration ≥50 μg/mL. The targeting effect of HFR and PhA-loaded HFR nanoparticles was not observed in folate receptor-negative HT-29 cells. The results indicated that HFR nanoparticles may be useful for targeted delivery of hydrophobic PDT agents and as a potential nanocarrier for dual chemo-and photodynamic therapies.