Biodegradable Progesterone Microsphere Delivery System for Osteoporosis Therapy

The purpose of this study was to formulate and characterize a controlled-release biodegradable delivery system of progesterone for the treatment or prevention of osteoporosis. Microspheres of progesterone were formulated using copolymers of poly(glycolic acid-co-dl-lactic acid)(PGLA 50/50 and PGLA 15/85) and poly(L-lactic acid)(L-PLA) of similar molecular weight by the emulsion solvent evaporation technique. The effects of process variables, such as volume fraction, polyvinyl alcohol (PVA) concentration, polymer composition, and stir speed during preparation, on the yield, encapsulation efficiency (EEF), particle size distribution, in vitro release profiles of progesterone, and surface morphology of progesterone microspheres were investigated. Increasing the volume fraction from 9% to 22% increased the EEF without significantly increasing the yield; however, the rate of progesterone release from the microspheres decreased. Increasing the PVA concentration from 1% to 5% had no significant influence on the EEF, but the rate of progesterone release from microspheres increased. Polymer composition had no significant effect on the EEF, but had a significant effect on the particle size distribution, surface morphology, and release rate of progesterone from the microspheres. Stir speed did not have a significant influence on the EEF; however, stir speed influenced particle size distribution and the rate of progesterone release from microspheres of the same sieve-size range. The results suggest that controlled release of progesterone is possible by varying the different process variables, and that PGLA 50/50 provided the slowest release of progesterone. This should provide a means of delivering progesterone for months for the treatment or prevention of osteoporosis in postmenopausal women.     

Biodegradable microparticulates of beta-estradiol: preparation and in vitro characterization

Beta-estradiol has been recommended for the long-term therapy of osteoporosis and its oral formulations are subjected to intensive first pass metabolism. The present investigation was aimed at preparing and characterizing biodegradable microparticles of beta-estradiol with polymers such as PLA, PLGA 85/15, PLGA 75/25, and their mixtures. The microparticles were prepared by solvent evaporation method using methylene chloride as a solvent and polyvinyl alcohol as a surfactant. The drug-polymer ratios were 1:3, 1:5, and 1:7. The prepared microparticles (twelve formulations) were tested for encapsulation efficiency and in vitro drug release in 50% methyl alcohol/phosphate buffer pH 7.4. The results showed that the encapsulation efficiency varied from 81 to 100% and the formulation fabricated from PLGA 85/15 (1:3) showed less burst and consistent long time release. This formulation when further characterized displayed irregular spherical shape with an average particle size of 72 µm. The crystallinity of the drug was reduced when investigated using X-ray diffractometry. No chemical interaction between the drug and the polymer was observed as evidenced by FT-IR analysis. The results indicated that beta-estradiol biodegradable microparticles with PLGA 85/15 (1:3) could be a suitable approach for long term therapy of osteoporosis.     

Biodegradable Microparticulates of Beta-Estradiol: Preparation and In Vitro Characterization

ABSTRACT

Beta-estradiol has been recommended for the long-term therapy of osteoporosis and its oral formulations are subjected to intensive first pass metabolism. The present investigation was aimed at preparing and characterizing biodegradable microparticles of beta-estradiol with polymers such as PLA, PLGA 85/15, PLGA 75/25, and their mixtures. The microparticles were prepared by solvent evaporation method using methylene chloride as a solvent and polyvinyl alcohol as a surfactant. The drug-polymer ratios were 1:3, 1:5, and 1:7. The prepared microparticles (twelve formulations) were tested for encapsulation efficiency and in vitro drug release in 50% methyl alcohol/phosphate buffer pH 7.4. The results showed that the encapsulation efficiency varied from 81 to 100% and the formulation fabricated from PLGA 85/15 (1:3) showed less burst and consistent long time release. This formulation when further characterized displayed irregular spherical shape with an average particle size of 72 µm. The crystallinity of the drug was reduced when investigated using X-ray diffractometry. No chemical interaction between the drug and the polymer was observed as evidenced by FT-IR analysis. The results indicated that beta-estradiol biodegradable microparticles with PLGA 85/15 (1:3) could be a suitable approach for long term therapy of osteoporosis.     

Evaluation of PLGA microspheres as delivery system for antitumor agent-camptothecin

Camptothecin (CPT) and its analogues are a new class of anticancer agents that have been identified over the past several years. Camptothecin exists in two forms depending on the pH: An active lactone form at pH below 5 and an inactive carboxylate form at basic or physiological neutral pH. Poly(lactide-co-glycolide) (PLGA) microspheres have been considered good delivery vehicles for CPT because of acidic microenvironment formed through PLGA degradation. The objective of this study is to investigate antitumor activity of CPT after it is encapsulated in PLGA microspheres. In this study, PLGA microspheres containing various CPT loadings were prepared and characterized. Cytotoxicity of these microspheres to B16 melanoma cells was then evaluated, and uptake of microspheres by B16 cells was also studied. Analysis of drug stability revealed that CPT is released from the microspheres in its active lactone form over the entire release duration. It was also found that there was no interaction between CPT and PLGA matrix within microspheres through Differential Scanning Calorimetry (DSC) and Fourien Transform Infrared Spectroscopy (FT-IR) and hign performance liquid chromatography (HPLC) studies. Cytotoxicity assay showed that CPT encapsulated in PLGA microspheres still retained its antitumor potency. Uptake study revealed quick uptake of the microspheres by B16 cells, which was desirable. It was concluded that PLGA microspheres were suitable delivery vehicles to stabilize and deliver CPT for the treatment of cancer.     

In Vitro and In Vivo Release of Naltrexone from Biodegradable Depot Systems

ABSTRACT

The aim of this study was to prepare poly(d, l-lactide) (PLA) microspheres containing naltrexone (NTX) by a solvent evaporation method, and to evaluate both in vitro and in vivo release characteristics and histopathological findings of tissue surrounding an implant formulation in rats.

This method enabled the preparation of microspheres of regular shape and relatively narrow particle size distribution. The in vitro release profiles of NTX from PLA microspheres showed the release of NTX did not follow zero-order kinetics. An initial burst release was observed, subsequently followed by a nearly constant rate of 0.4% per day after ten days. The cumulative amount of NTX released at the end of 60 days was 80%. Compressed microspheres showed near zero-order sustained release of NTX for 360 days. The plasma NTX levels in rats showed that for compressed microspheres NTX concentrations were constant and exceeded 2 ng/mL for 28 days. Throughout the 28 days of study, the implantations cause a minor inflammatory response, which can be regarded as a normal defence mechanism. The sustained release performance of NTX from the biodegradable depot systems may provide a reliable, convenient, and safe mechanism for the administration of NTX for the long-term treatment of opioid dependence.     

Mucoadhesive tablets for the vaginal delivery of progesterone: in vitro evaluation and pharmacokinetics/pharmacodynamics in female rabbits

Objective: To develop mucoadhesive tablets for the vaginal delivery of progesterone (P4) to overcome its low oral bioavailability resulting from drug hydrophobicity and extensive hepatic metabolism.

Methods: The tablets were prepared using mixtures of P4/Pluronic^® F-127 solid dispersion and different mucoadhesive polymers. The tablets physical properties, swelling index, mucoadhesion and drug release kinetics were evaluated. P4 pharmacokinetic and pharmacodynamic properties were evaluated in female rabbits and compared with vaginal micronized P4 tablets and intramuscular (IM) P4 injection, respectively.

Results: The tablets had satisfactory physical properties and their swelling, in vitro mucoadhesion force and ex vivo mucoadhesion time were dependent on tablet composition. Highest swelling index and mucoadhesion time were detected for tablets containing 20% chitosan-10% alginate mixture. Most tablets exhibited burst release (～25%) during the first 2?h but sustained the drug release for ～48?h. In vivo study showed that chitosan-alginate mucoadhesive tablets had ～2-fold higher P4 mean residence time (MRT) in the blood and 5-fold higher bioavailability compared with oral P4. Further, same tablets showed 2-fold higher myometrium thickness in rabbit uterus compared with IM P4 injection.

Conclusion: These results confirm the potential of these mucoadhesive vaginal tablets to enhance P4 efficacy and avoid the side effects associated with IM injection.     

Biodegradable Materials for Bone Repairs:A Review

With attractive research and development of biomaterials,more and more opportunities have been brought to the treatments of human tissue repairs.The implant is usually no need to exist in the body accompanied with the recovery or regeneration of the tissue lesions,and the long-term effect of exotic substance to human body should be reduced as lower as possible.For this purpose,biodegradable materials,including polymers, magnesium alloys and ceramics,have attracted much attention for medical applications due to their biodegradable characters in body environment.This paper in turn introduces these three different types of widely studied biodegradable materials as well as their advantages as implants in applications for bone repairs.Relevant history and research progresses are summarized.     

Biodegradable drug delivery system for the treatment of bone infection and repair

A drug delivery system (DDS) which provides a sustained release of antibiotics at the focal site either singly, or in combination with a bone stimulating factor could both eliminate infection and increase the number of potentially healthy osteogenic cells. In this study, we address the use of a degradable gelatin DDS, for the combined release of therapeutic levels of both gentamicin and growth hormone (GH). An initial bolus release was observed during the first 24 h followed by a reduced, but sustained, release for both drugs up to 14 days. Bioactivity of gentamicin was demonstrated by growth inhibition of Staphylococcus aureus for over 96 h with a mean zone of inhibition of 29.4 mm (±0.19) for the time period studied. Furthermore, GH was shown to have a direct effect on primary human osteoblast-like (HOB) cells, stimulating proliferation and enhancing their differentiation. Site-specific drug delivery offers the advantage of localizing a drug directly at the target site, thus minimizing systemic effects. The results of this study suggest that gelatin is a good DDS for the combined release of drugs. In addition, gelatin is both biocompatible and biodegradable, thus making it a promising DDS for the management of acute and chronic bone and tissue infection such as osteomyelitis. © 1999 Kluwer Academic Publishers     

生物可降解聚乳酸骨科材料研究进展

在骨外科中，聚乳酸中已成为十分重要的生物可降解高分子材料，用作为固定器材，骨诱生支撑体和药物控制缓释材料，本文树其研究进展作了综合评述，对存在问题也进行了一些讨论。     

Facile method for fabricating titania spheres for chromatographic packing

Titania (TiO₂) spheres were fabricated by a solvent evaporation process in which anhydrous ethanol was used as the only solvent. This is a simple and novel route for the fabrication of TiO₂ spheres. The spheres have a narrow particle size distribution and an average diameter of approximately 1.0 µm. The crystal structure of the prepared spheres was improved by high-temperature processing. A possible mechanism for the formation and growth of the spheres is proposed in which titanic acid molecules react with each other through hydroxyl condensation to form primary TiO₂ particles. These aggregate and increase in size by surface reaction, and finally form spheres.     

Challenges and Solutions for the Additive Manufacturing of Biodegradable Magnesium Implants

Due to their capability of fabricating geometrically complex structures, additive manufacturing (AM) techniques have provided unprecedented opportunities to produce biodegradable metallic implants—especially using Mg alloys, which exhibit appropriate mechanical properties and outstanding biocompatibility. However, many challenges hinder the fabrication of AM-processed biodegradable Mg-based implants, such as the difficulty of Mg powder preparation, powder splash, and crack formation during the AM process. In the present work, the challenges of AM-processed Mg components are analyzed and solutions to these challenges are proposed. A novel Mg-based alloy (Mg–Nd–Zn–Zr alloy, JDBM) powder with a smooth surface and good roundness was first synthesized successfully, and the AM parameters for Mg-based alloys were optimized. Based on the optimized parameters, porous JDBM scaffolds with three different architectures (biomimetic, diamond, and gyroid) were then fabricated by selective laser melting (SLM), and their mechanical properties and degradation behavior were evaluated. Finally, the gyroid scaffolds with the best performance were selected for dicalcium phosphate dihydrate (DCPD) coating treatment, which greatly suppressed the degradation rate and increased the cytocompatibility, indicating a promising prospect for clinical application as bone tissue engineering scaffolds.     

Development of biodegradable microcapsules as carrier for oral controlled delivery of amifostine

The primary objective of this project was to develop a biodegradable, orally active controlled-release formulation of amifostine. Development of such a formulation will mark an important advancement in the areas of chemoprotection and radioprotection. Biodegradable microcapsules of amifostine were prepared using poly(lactide/glycolide) (PLGA 50:50). The microcapsules were prepared by solvent evaporation technique. Amifostine-loaded microcapsules were evaluated for particle size, surface morphology, thermal characteristics, and drug release. Particle size and surface morphology were determined using scanning electron microscopy (SEM). Thermal characterization was conducted using differential scanning calorimetry (DSC). In vitro release study was performed at 37°C using phosphate buffer (pH 7.4). Amifostine release was calculated by measuring the amount of drug remaining within the microcapsules at a specific sampling time. The amount of amifostine in the samples was determined by high-performance liquid chromatography (HPLC) using an electrochemical detector. The yield of microcapsules was 75%. Scanning electron microscopy pictures revealed that the particles were nearly spherical and smooth with an average size of 54 µm. Differential scanning calorimetry thermograms showed that microcapsules loaded with amifostine have a glass transition at 39.4°C, and the melting endotherm of amifostine was absent. The absence of a melting endotherm for amifostine was an indication that amifostine was not in the crystalline state in the microcapsules, but rather in the form of a solid solution in PLGA. Approximately 50% amifostine was released during the first 6 hr of the in vitro release study. The drug, however, continued to release over the observed period of 12 hr during which 92% amifostine was released.     

Processing conditions for the production of polystyrene microcapsules containing demineralized water

Microencapsulation has been important for engineering, biology, medicine, and several other fields of science. Microencapsulation is an effective way to protect the encapsulated material (e.g. an aqueous solution or pharmaceutical drug) and control its release to the external environment. Microcapsules are also used for producing anticorrosion systems and, in this case, studies about polymeric microcapsules containing acid solutions are relevant. In this paper, polystyrene microcapsules containing demineralized water were produced. The influence of the core-to-shell ratio, evaporation temperature, and the presence of sodium chloride and a surfactant on the yield of the microencapsulation process was evaluated. Microcapsules were characterized by scanning electron microscopy (SEM), and thermogravimetry that revealed the morphology and thermal behavior of microcapsules in response to changing core-to-shell ratios. SEM images showed mononuclear microcapsules with smooth surfaces. The results indicated that a core-to-shell ratio of 2:1 showed the best encapsulation performance under the conditions of this study. An increase in yield of about 38% was achieved by reducing the evaporation temperature. In addition, the yields obtained in this research are considerably higher than those found in literature.     

Development and in vitro characterization of chitosan-based microspheres for nasal delivery of promethazine

Conventional and composed promethazine-loaded microspheres were prepared by spray drying of chitosan solution systems and double water-in-oil-in-water (W/O/W) emulsion systems, respectively. Double emulsions were prepared in two different feed concentrations, with chitosan dissolved in both water phases, and ethylcellulose dissolved in oil phase. Swelling and bioadhesive properties of the microspheres depended on the chitosan content, type and the feed concentration of spray-dried system. Results obtained suggested that better ethylcellulose microcapsules with promethazine in the chitosan matrix were formed when less concentrated emulsion systems were spray-dried. Thus, in case of such a system, with ethylcellulose/chitosan weight ratio of 1:2, prolonged promethazine release was obtained.     

Preparation of alginate microspheres by water-in-oil emulsion method for drug delivery: Effect of Ca2+ post-cross-linking

Alginate microspheres were prepared by a water-in-oil emulsion solvent diffusion method. The alginate microspheres were post-cross-linked with Ca²⁺ ions. Influence of Ca²⁺ concentration on the characteristics and drug release behaviors of alginate microspheres was evaluated. Blue dextran was used as a water-soluble model drug. The non-cross-linked alginate microspheres were less than 100 μm in size and had a spherical shape. The cross-linked alginate microspheres were also spherical in shape with a rougher surface but their particle sizes were larger than 100 μm. The drug encapsulation efficiency of the non-cross-linked alginate microspheres was very high (82%). The drug encapsulation efficiency of alginate microspheres cross-linked with 5% and 10% Ca²⁺ concentrations were similar to the non-cross-linked microspheres. The in vitro drug releases of the cross-linked alginate microspheres showed prolong release profiles. The cumulative release of blue dextran decreased as the Ca²⁺ concentration increased. Thus, Ca²⁺-post-cross-linked alginate microspheres show possibility for use as controlled-release drug carriers.     

A Comparison of Corrosion Behavior in Saline Environment: Rare Earth Metals (Y, Nd, Gd, Dy) for Alloying of Biodegradable Magnesium Alloys

Rare earth(RE) metals are widely used as the alloying elements in biodegradable magnesium alloys as medical implants.However,corrosion behavior of pure RE metals not only in physiological media but also in chlorinated saline environment is not well understood.In the present work,the RE metals Y,Nd,Gd and Dy are selected to investigate their corrosion behavior in 0.1 mol/L NaCl solution with immersion and electrochemistry techniques.As indicated,corrosion of the currently investigated RE metals is promoted in the order of Dy,Y,Gd and Nd.In terms of electrochemical response,such a sequence correlates with the increased impedance and the decreased corrosion rate(CR).These RE metals manifest weak ability for passivation in the native surface.Then,reaction with aqueous solution easily happens through the anodic dissolution and cathodic hydrogen evolution.The corrosion products,RE(OH)3,adhered on the surface of RE metals,do not have an appreciable power to resist the reaction proceeding with corrosive chloride ions.In contrast to pure Mg,the RE metals,including Y,Nd,Gd and Dy,exhibit significantly fragile corrosion resistance in saline media.Therefore,with the current findings,it is impossible to reveal a well-defined correlation of corrosion resistance between RE-containing Mg alloy and RE metal itself.     

Local antibiotic delivery systems for the treatment of osteomyelitis – A review

Osteomyelitis, an inflammatory process accompanied by bone destruction, is caused by infective microorganisms. The high success rates of antimicrobial therapy by conventional routes of administration in controlling most infectious diseases have not yet been achieved with osteomyelitis for several reasons. Local and sustained availability of drugs have proven to be more effective in achieving prophylactic and therapeutic outcomes. This review introduces osteomyelitis – its present options for drug delivery and their limitations, and the wide range of carrier materials and effective drug choices. Local drug delivery for osteomyelitis is a topic of importance for more than 20 years. Carrier materials used for local delivery of antibiotics may be classified as nonbiodegradable and biodegradable. Commonly used non biodegradable carrier materials are polymethyl methacrylate (PMMA), Acrylic beads, PMMA bone cement etc. and biodegradable materials are hydroxyapatite block, bioactive glass ceramics, collagen sponge, polylactide/ployglycolide implants. Both the systems release antibiotic at concentrations exceeding the minimum inhibitory concentrations (MICs) for the most common pathogens involved in osteomyelitis without causing any adverse systemic effects although non biodegradable beads are to be removed from the surgical site after completion of antibiotic release.     

Formulation and evaluation of injectable in situ forming microparticles for sustained delivery of lornoxicam

The objective of this study is to formulate biodegradable in situ microparticles (ISM) containing lornoxicam for post-operative and arthritic pain management. ISM emulsions were prepared according to 2⁵ full factorial experimental design to investigate the influence of formulation variables on the release profile of the drug. The independent variables studied are the polymer type, polymer inherent viscosity, polymer concentration, oil type and polymer:oil ratio. In vitro drug release, microscopical examination, particle size determination and syringeability measurement were selected as dependent variables. The effect of γ-sterilization on the prepared formulae was also examined. The prepared formulae showed extended drug release over two weeks, and flow time below 5?s/ml. Scanning electron microscope revealed that the prepared microparticles were spherical in shape, with diameter ranging from 3.45 to 22.78?µm. In vivo pharmacokinetic evaluation of two selected optimum formulations in rabbits showed prolonged drug absorption indicated by delayed T_max and the extended mean residence time. In conclusion, the prepared injectable ISM could be a promising approach for providing extended delivery of lornoxicam with low initial burst effect.     

Deformable liposomes by reverse-phase evaporation method for an enhanced skin delivery of (+)-catechin

Background: (+)-catechin, as the most common catechin isomer, is recognized to be an antioxidant which benefits the skin in many ways. The purpose of the present study was to prepare and evaluate a suitable liposomal delivery systems for (+)-catechin topical application.

Methods: In this study, catechin-loaded conventional liposomal delivery system, deformable conventional liposomal delivery system and deformable liposomes prepared by reverse-phase evaporation (REV) method were compared. The three systems were characterized for liposome particle size, zeta-potential, entrapment efficiency, drug release, permeability across porcine skin and catechin deposition in the skin.

Results: It was revealed that the size of deformable conventional liposomes before freeze-drying and deformable REV liposomes after freeze-drying range from 335.6?±?71.7?nm to 551.1?±?53.4?nm, respectively, which were considered to be suitable for skin delivery. The deformable REV liposomes had a higher aqueous volume and thus were able to entrap greater amounts of hydrophilic (+)-catechin (50.0?±?5.9%) compared to conventional (30.0?±?3.8%) and deformable conventional liposomes (36.1?±?4.6%). All liposomal formulations exhibited a prolonged catechin release. Compared to deformable liposomes, the REV deformable liposomes showed a significantly better deposition of (+)-catechin while catechin solution did not permeate into the porcine ear skin.

Conclusion: Among all formulations studied, deformable REV liposomes were considered to be favorable for catechin topical delivery.