Encapsulation of Azithromycin Ion Pair in Liposome for Enhancing Ocular Delivery and Therapeutic Efficacy on Dry Eye.

The aim of this work was to design a novel ocular delivery carrier based on liposomes loaded with azithromycin (AZM) for the treatment of dry eye (DE) disease. To improve the drug loading efficiency, an AZM-cholesteryl hemisuccinate (CHEMS) ion pair (ACIP) was first prepared, and the successful formation of the ACIP was characterized by Fourier transform infrared spectroscopy (FTIR), differential scanning calorimetry (DSC), and X-ray powder diffraction (XRD), which demonstrated a stable interaction between CHEMS and AZM. The ACIP-loaded liposome (ACIP-Lip) appeared as spherical particles under TEM, with a uniform particle size of 60 ± 2 nm and zeta potential of -20.3 ± 4.6 mV. The entrapment efficiency (EE) and drug loading (DL) of ACIP-Lip were greatly improved to 95.6 ± 2.0 and 9.2 ± 0.7%, respectively, which was attributed to the enhanced loading capacity of the liposomes through use of the ion pair and addition of MCT. ACIP-Lip also exhibited a high stability during a 3 month storage period at both 4 and 25 °C. In vitro release of AZM from ACIP-Lip was pH-dependent, with a more rapid release at pH 6.0 than at pH 7.4, which is beneficial for ocular therapy. Furthermore, the corneal permeation of AZM was enhanced by ACIP-Lip, demonstrating an apparent permeability coefficient ( Papp × 106) of 8.92 ± 0.56 cm/s, which was approximately 2-fold greater that of the AZM solution. Finally, an in vivo pharmacodynamical study showed that the essential symptoms of DE rats were significantly improved by ACIP-Lip, as it was highly efficient and superior compared to hyaluronic acid sodium eye drops available on the market. Hence, ACIP-Lip is a promising formulation for DE treatment.

Silica nanoparticles on the oral delivery of insulin.

INTRODUCTION: When intravenous or subcutaneous administration of insulin, various side effects or possible risks have been reported. Oral administration of insulin has significant advantages of convenience, painless and mimetic endogenous insulin pathway, and thus it presents patients compliance, protects pancreatic ß cells and lessens adverse effects caused by long-term injection. This challenging oral delivery of insulin can be achieved by promising silica nanoparticles (SNs), especially mesoporous silica nanoparticles (MSNs), with controllable morphology and high loading efficiency. This review presents the synthesis and physiological behaviors of SNs such as in vivo and in vitro degradation, absorption, distribution, and excretion, as well as preparations of oral insulin based on SNs. As well, this review will provide insights for innovative oral delivery of SNs and insulin. AREAS COVERED: Promising SNs and MSNs have gained interests for application in oral drug delivery of insulin. EXPERT OPINION: After synthesis under proper conditions and methods, promising SNs with controllable structure and suitable stability can be synthesized. By improving permeability and penetration, achieving controlled release and adjusting physiological processes, functionalization on SNs by active groups, molecules, or polymers is necessary for oral delivery of insulin.

Polymer-Encapsulated Aß Peptide Fragments as an Oligomeric-Specific Vaccine for Alzheimer's Disease.

Vaccination is regarded as one of the most cost-effective and reliable methods for combating disease. We have developed a new method for an oligomeric Aß-specific AD vaccination using polymer micelle-encapsulated peptide fragments, which overcome many problems of vaccination associated with the direct use of the Aß1­42 peptide. We studied different encapsulated forms of shortened Aß peptides with and without the entire T cell epitope in an APP/PS1 mouse model. After two inoculations with encapsulated Aß fragments, antibodies were produced in all mice with antibody titer greater than 1:12,800. No anti-polymer antibodies were detected after five inoculations, and none of the injected mice showed any adverse effects throughout experimentation. Anti-Aß antibodies from our polymer-encapsulated vaccine were able to bind to A plaques in the brain of our mice, and were able to specifically recognize oligomeric Aß. Our results suggest that the safety and efficacy issues previously encountered in other Aß vaccination trials may be successfully addressed by using micelle-encapsulated peptides. These shorter Aß fragments are also easier to synthesize and more cost-effective than the highly hydrophobic full-length Aß1­42 peptide.

Development of an ultra-thin film comprised of a graphene membrane and carbon nanotube vein support.

Graphene, exhibiting superior mechanical, thermal, optical and electronic properties, has attracted great interest. Considering it being one-atom-thick, and the reduced mechanical strength at grain boundaries, the fabrication of large-area suspended chemical vapour deposition graphene remains a challenge. Here we report the fabrication of an ultra-thin free-standing carbon nanotube/graphene hybrid film, inspired by the vein-membrane structure found in nature. Such a square-centimetre-sized hybrid film can realize the overlaying of large-area single-layer chemical vapour deposition graphene on to a porous vein-like carbon nanotube network. The vein-membrane-like hybrid film, with graphene suspended on the carbon nanotube meshes, possesses excellent mechanical performance, optical transparency and good electrical conductivity. The ultra-thin hybrid film features an electron transparency close to 90%, which makes it an ideal gate electrode in vacuum electronics and a high-performance sample support in transmission electron microscopy.

Scratch-resistant, highly conductive, and high-strength carbon nanotube-based composite yarns.

High-strength and conductive carbon nanotube (CNT) yarns are very attractive in many potential applications. However, there is a difficulty when simultaneously enhancing the strength and conductivity of CNT yarns. Adding some polymers into CNT yarns to enhance their strength will decrease their conductivity, while treating them in acid or coating them with metal nanoparticles to enhance their conductivity will reduce their strength. To overcome this difficulty, here we report a method to make high-strength and highly conductive CNT-based composite yarns by using a continuous superaligned CNT (SACNT) yarn as a conductive framework and then inserting polyvinyl alcohol (PVA) into the intertube spaces of the framework through PVA/dimethyl sulphoxide solution to enhance the strength of yarns. The as-produced CNT/PVA composite yarns possess very high tensile strengths up to 2.0 GPa and Young's moduli more than 120 GPa, much higher than those of the CNT/PVA yarns reported. The electric conductivity of as-produced composite yarns is as high as 9.2 × 10(4) S/m, comparable to HNO(3)-treated or Au nanoparticle-coated CNT yarns. These composite yarns are flexible, lightweight, scratch-resistant, very stable in the lab environment, and resistant to extremely humid ambient and as a result can be woven into high-strength and heatable fabrics, showing potential applications in flexible heaters, bullet-proof vests, radiation protection suits, and spacesuits.