Porous Core/Dense Shell PLA Microspheres Embedded with High Drug Loading of Bupivacaine Crystals for Injectable Prolonged Release.

Objective of the study was to design an injectable microsphere preparation with high drug loading of bupivacaine for prolonged release and local anesthetic. PLA or PLGA was used as the biodegradable matrix material to fabricate microspheres with the o/w emulsification-solvent evaporation method. The characterization of bupivacaine microspheres was observed by SEM, DSC, and XRPD. The microsphere preparation and extended drug release, as well as the plasma drug concentration and sciatic nerve blockade after injection of the microsphere formulation to rats were investigated. High drug-loading microspheres of more than 70% were successfully obtained with extended drug release over 5 days in vitro depending on the type of matrix and the feed ratio of drug to polymer. SEM, DSC, and XRPD results verified a novel microsphere structure characterized as the porous core composed of PLA material and form II bupivacaine crystals and dense shell formed of PLA layer. The mechanism that bupivacaine was dissolved inside the microsphere and diffused across the dense shell was suggested for drug release in vitro. The optimized PLA microsphere formulation showed low and steady plasma drug concentration over 5 days and prolonged duration of sensory and motor blockade of sciatic nerve lasted more than 3 days. Results indicated that the porous core-shell structure of PLA microsphere formulation would provide enormous potential as an injectable depot for locally prolonged delivery of bupivacaine and control of postoperative pain.

Enhanced Antitumor Efficacy of Curcumin-Loaded PLGA Nanoparticles Coated with Unique Fungal Hydrophobin.

Modifications to the surface chemistry, charge, and hydrophilicity/hydrophobicity of nanoparticles are applicable approaches to the alterations of the in vivo fate of intravenously administered nano-sized drug carriers. The objective of this study is to investigate the in vitro and in vivo antitumor efficacies of curcumin PLGA nanoparticles in relation to their surface structural modification via self-assembling coating with unique fungal hydrophobin. The hydophobin-coated curcumin PLGA nanoparticles (HPB PLGA NPs) were obtained by simply soaking curcumin-loaded PLGA nanoparticles (PLGA NPs) in aqueous fungal hydrophobin solution. The in vitro drug release behavior of the HPB PLGA NPS was also tested. The cytotoxicity and cellular uptake of these nanoparticles were determined in HepG2, A549, and Hela cell lines using MTT assay method and CLSM observation. The in vivo antitumor activity was evaluated in Hela tumor xenografted mice model. Compared with the PLGA NPs, the size and zeta potential of the nanoparticles were changed after hydrophobin coating, whereas similar in vitro release pattern was observed. The pharmacodynamics study showed prolonged blood retention of both nano-formulations than that of free curcumin, but no significant difference between the hydrophobin coated and uncoated nanoparticles. It was found that HPB PLGA NPs had increased cytotoxicities, higher cellular uptake, and improved antitumor efficacy. Surface modification of nanoparticles via self-assembling of hydrophobin is a convenient and promising method of changing particle surface physiochemical properties and antitumor performances. Further investigations, especially on tissue distribution, were needed to assess the potential application of the hydrophobin self-assembling coating in nano-drug delivery carriers.

Self-assembled micelles composed of doxorubicin conjugated Y-shaped PEG-poly(glutamic acid)2 copolymers via hydrazone linkers.

In this work, micelles composed of doxorubicin-conjugated Y-shaped copolymers (YMs) linked via an acid-labile linker were constructed. Y-shaped copolymers of mPEG-b-poly(glutamate-hydrazone-doxorubicin)2 and linear copolymers of mPEG-b-poly(glutamate-hydrazone-doxorubicin) were synthesized and characterized. Particle size, size distribution, morphology, drug loading content (DLC) and drug release of the micelles were determined. Alterations in size and DLC of the micelles could be achieved by varying the hydrophobic block lengths. Moreover, at fixed DLCs, YMs showed a smaller diameter than micelles composed of linear copolymers (LMs). Also, all prepared micelles showed sustained release behaviors under physiological conditions over 72 h. DOX loaded in YMs was released more completely, with 30% more drug released in acid. The anti-tumor efficacy of the micelles against HeLa cells was evaluated by MTT assays, and YMs exhibited stronger cytotoxic effects than LMs in a dose- and time-dependent manner. Cellular uptake studied by CLSM indicated that YMs and LMs were readily taken up by HeLa cells. According to the results of this study, doxorubicin-conjugated Y-shaped PEG-(polypeptide)2 copolymers showed advantages over linear copolymers, like assembling into smaller nanoparticles, faster drug release in acid, which may correspond to higher cellular uptake and enhanced extracellular/intracellular drug release, indicating their potential in constructing nano-sized drug delivery systems.

Sustained liver targeting and improved antiproliferative effect of doxorubicin liposomes modified with galactosylated lipid and PEG-lipid.

In this study, a cleavable PEG-lipid (methoxypolyethyleneglycol 2000-cholesteryl hemisuccinate, PEG(2000)-CHEMS) linked via ester bond and galactosylated lipid ((5-cholesten-3beta-yl) 4-oxo-4-[2-(lactobionyl amido) ethylamido] butanoate, CHS-ED-LA) were used to modify doxorubicin (DOX) liposome. DOX was encapsulated into conventional liposomes (CL), galactosylated liposomes (modified with CHS-ED-LA, GalL), pegylated liposomes (modified with PEG(2000)-CHEMS, PEG-CL), and pegylated galactosylated liposomes (modified with CHS-ED-LA and PEG(2000)-CHEMS, PEG-GalL) using an ammonium sulfate gradient loading method and then intravenously injected to normal mice. Both PEG-GalL DOX and GalL DOX gave relatively high overall drug targeting efficiencies to liver ((T(e))(liver)) and were mainly taken up by hepatocyte. However, PEG-GalL DOX showed unique "sustained targeting" characterized by slowed transfer of DOX to liver and reduced peak concentrations in the liver. The biodistribution and antitumor efficacy of various DOX preparations were studied in hepatocarcinoma 22 (H22) tumor-bearing mice. The inhibitory rate of PEG-GalL DOX to H22 tumors was up to 94%, significantly higher than that of PEG-CL DOX, GalL DOX, CL DOX, and free DOX, although the tumor distribution of DOX revealed no difference between PEG-GalL DOX and PEG-CL DOX. Meanwhile, the gradual increase in the liver DOX concentration due to the sustained uptake of PEG-GalL DOX formulations resulted in lower damage to liver. In conclusion, the present investigation indicated that double modification of liposomes with PEG(2000)-CHEMS, and CHS-ED-LA represents a potentially advantageous strategy in the therapy of liver cancers or other liver diseases.

Preparation, characterization and pharmacokinetics evaluation of clarithromycin-loaded Eudragit(®) L-100 microspheres.

The aim of this work was to prepare pH-dependent clarithromycin microsphere formulation by emulsion solvent evaporation method, employing Eudragit(®) L-100. Prepared microspheres were evaluated by carrying out in vitro release and in vivo pharmacokinetics studies. Drug-polymer interactions were studied by differential scanning calorimetry, X-ray diffractometry analyses and results showed that clarithromycin was molecularly dispersed in the polymer. The particle size distribution of microspheres was found over the range of 10~50 µm. The drug is hardly released in the HCl solution pH 1.2 in the first 2 h, but is rapidly released in phosphate buffer pH 7.2, and the cumulated release reached 98.1 % at 8 h. The pharmacokinetic profiles were conducted open, randomized, two-period crossover design with a 7-day interval between doses in healthy beagle dogs. The results indicated that the extent of absorption of the clarithromycin-load microspheres was the same as pure drug, but different in the rate of drug absorption in vivo.

Improvement of the Antitumor Efficacy of Intratumoral Administration of Cucurbitacin Poly(Lactic-co-Glycolic Acid) Microspheres Incorporated in In Situ-Forming Sucrose Acetate Isobutyrate Depots.

Localized drug delivery strategies for cancer therapy have been introduced for decades as a means of increasing drug concentration at tumor target site and minimizing systemic toxicities. In this paper, a combination of microspheres (MSs) and sucrose acetate isobutyrate (SAIB) in situ-forming implants (ISFIs) was evaluated for improving antitumor efficacy via intratumoral injection. Monodispersed cucurbitacin (Cuc)-loaded Poly (lactic-co-glycolic acid) (PLGA) MSs with mean diameter of about 5 µm were fabricated by Shirasu porous Glass (SPG) membrane emulsification technique, and their properties were investigated. The in vitro drug release pattern, antimelanoma efficiency, and drug distribution in tumor of three different intratumoral injection systems, that is, MSs, SAIB ISFIs, and combination of MSs and SAIB ISFIs (SAIB-MSs), was investigated. The Cuc-loaded MSs prepared by PLGA (LA/GA = 50:50, inherent viscosity = 0.87 dL/g), has an appropriate release pattern with lower initial burst and delayed drug release. SAIB-MSs have a much slower drug release rate than that of MSs or SAIB ISFIs. SAIB-MSs showed the best antitumor efficacy in melanoma-bearing mice model, and the results of drug distribution in tumor revealed that the incorporation MSs in SAIB solution obviously extended the residence of drug in tumor. The low Cuc concentration in tumor periphery region after intratumoral administration of SAIB-MSs demonstrated poor drug penetration of this system. For further improving the antitumor efficacy of intratumoral chemotherapy, elegant designing to carriers with both extended residency and wide drug distribution in tumor is needed.

Thiolated eudragit-based nanoparticles for oral insulin delivery: preparation, characterization, and evaluation using intestinal epithelial cells in vitro.

This work deals with the synthesis of insulin loaded nanoparticles (NPs) composed of thiolated Eudragit L100 (Eul-cys) and reduced glutathione (GSH) as potential nanocarriers for oral delivery of insulin. Perfectly spherical NPs with an average particle size of nearly 200-300 nm are prepared. The insulin release from Eul-cys/GSH and Eul-cys NPs in PBS (pH 7.4) shows that GSH can slightly decrease the release rate of insulin. Eul-cys in combination with GSH or sodium caprate (SC) is evaluated for its permeation enhancing effect of FITC-insulin using the Caco-2 monolayer and Caco-2/HT29-MTX co-cultured cells models. SC results in greater permeation enhancement compared to GSH. However, GSH proves to be less toxic. Paracellular transport of insulin represents the main mechanism by which the NPs facilitate insulin permeation through the intestinal epithelium, whereas a number of NPs are also taken up by the cells and release insulin within the cells.