Tracking the effect of microspheres size on the drug release from a microsphere/sucrose acetate isobutyrate (SAIB) hybrid depot in vitro and in vivo

The effects of particle size of microspheres on the drug release from a microsphere/sucrose acetate isobutyrate (SAIB) hybrid depot (m-SAIB) was investigated to develop a long-term sustained release drug delivery system with low burst release both in vitro and in vivo. A model drug, risperidone, was first encapsulated into PLGA microspheres with different particle sizes using conventional emulsification and membrane emulsification methods. The m-SAIB was prepared by dispersing the risperidone-microspheres in the SAIB depot. The drug release from m-SAIB was double controlled by the drug diffusion from the microspheres into SAIB matrix and the drug diffusion from the SAIB matrix into the medium. Large microspheres (18.95?±?18.88?µm) prepared by the conventional homogenization method exhibited porous interior structure, which contributed to the increased drug diffusion rate from microspheres into SAIB matrix. Consequently, m-SAIB containing such microspheres showed rapid initial drug release (C_max?=_?110.1?±54.2?ng/ml) and subsequent slow drug release (C_s(4–54d)=?2.7?±?0.8?ng/ml) in vivo. Small microspheres (5.91?±?2.24?µm) showed dense interior structure with a decreased drug diffusion rate from microspheres into SAIB matrix. The initial drug release from the corresponding m-SAIB was significantly decreased (C_max?=_?40.9?±?13.7?ng/ml), whereas the drug release rate from 4 to 54 d was increased (C_s(4–54d)=4.1?±?1.0?ng/ml). By further decreasing the size of microspheres to 3.38?±?0.70?µm, the drug diffusion surface area was increased, which subsequently increased the drug release from the m-SAIB. These results demonstrate that drug release from the m-SAIB can be tailored by varying the size of microspheres to reduce the in vivo burst release of SAIB system alone.     

Comparative In Vitro evaluation of cumulative release of the urinary antiseptics Nalidixic acid,Pipemidic acid,Cinoxacin, and norfloxacin from white beeswax Microspheres

Abstract

The in vitro diffusion of nalidixic acid (1), pipemidic acid (2), cinoxacin (3), and norfloxacin (4) was studied. The transfer rate constants (k_d) from simulated gastro-intestinal juices to simulated plasma, throughout artificial wall lipid membranes, were defined. The k_d values suggested that the four drugs are absorbed both in gastric and intestinal environments in similar amounts. To obtain lack of gastric unwanted effects white beeswax microspheres containing 1, 2, 3, and 4 were investigated as a vehicle for the drug intestinal release; they were prepared by the meltable dispersion process using wetting agents. Discrete, reproducible free flowing microspheres were obtained. The drug content increased when the particle size growed; it ranged from 4% to 18%. More than 95% of the isolated microspheres were of particle size range 100–500 μm. The drug release was evaluated in vitro. Dissolution of entrapped active ingredients was greatly retarded allowing absorption only in the intestinal tract as result of microsphere formation.     

Manufacture,Characterization, and Release Profiles of Insulin-Loaded Mesoporous PLGA Microspheres

This paper reports the fabrication of insulin-loaded mesoporous microspheres by a double emulsion-solvent evaporation technique using poly(lactic acid-co-glycolic acid) (PLGA) as carrier materials. PLGA solutions with two different concentrations (4% and 5%) were used as the oil phases to fabricate the mesoporous microspheres. The morphology and the particle size distribution of final microspheres were studied by optical microscope, scanning electronic microscope (SEM), and Malvern 2600 sizer, respectively. The mesoporous microspheres were monodisperse with an average diameter of 7 ± 3.5 µm. Insulin, as a model drug, was encapsulated into the final microspheres. In vitro release studies suggested that insulin was continuously released from the medicated microspheres. Furthermore, the final microspheres obtained from 4% PLGA solution showed a small “burst release” effect for their dense structures, which shortened the lag time to the effective plasma concentration. To summarize, the insulin-loaded PLGA microsphere are very promising for use in pharmaceutical applications.     

The effect of inorganic salt type and concentration on hydrophilic drug loading into microspheres using the emulsion/solvent diffusion method

Aim: In order to avoid gastric irritation caused by tolmetin sodium (TS), gastro resistant Eudragit® S 100 microsphere formulations were prepared with the emulsion/solvent diffusion method.

Materials: Considering the high water solubility of the TS molecule, the effects of the presence of inorganic salt (NaCl, NaBr and KH₂PO₄; 0.1?M and 1.0?M) in external phase and external phase pH on the encapsulation efficiency were evaluated.

Results: Percentage yield value was found to vary between 55.8% and 72.1%. Improvement in encapsulation efficiency was determined by increasing concentrations of NaCl, NaBr and KH₂PO₄. The microspheres were observed to have a spherical shape and the measured particle size values varied between 52.1 and 81.5?µm. The released amounts of the drug were found to be low as the inorganic salt concentrations increased.

Conclusion: Conclusively, drug release in stomach pH was significantly prevented by the microspheres prepared using Eudragit® S 100 polymer, and these formulations are considered to be a model for other orally administered drugs with similar problems.     

A novel PHBV/HA microsphere releasing system loaded with alendronate

Microspheres of poly(β-hydroxybutyrate-co-β-hydroxyvalerate) (PHBV) incorporated with hydroxyapatite (HA) and loaded with alendronate (AL), an osteoporosis preventing drugs, were prepared by single emulsion technique. Several methods were used to evaluate this novel drug carrier microsphere system (referred as PHBV/HA–AL). Fourier transform infrared (FTIR) was used to evaluate the enwrapping of HA and the X-ray diffraction (XRD) analysis further confirmed the success. The morphology of PHBV/HA–AL microspheres was observed by scanning electron microscope (SEM), showing rough surface with HA particles enwrapped in the PHBV matrix. The in vitro drug releasing profile of PHBV/HA–AL system was investigated in a 26-day period. There is a sustained releasing pattern after a slight burst release during the first few days. Additionally, rabbit mesenchymal stem cells (MSCs) were used to evaluate the cytotoxicity of the PHBV/HA–AL composites. This controlled release system can well support the proliferation of MSCs. The novel PHBV/HA–AL controlled release system is promising for bone repair therapy.     

Biomimetic mineralization of calcium carbonate/carboxymethylcellulose microspheres for lysozyme immobilization

Porous calcium carbonate/carboxymethylcellulose (CaCO₃/CMC) microspheres were prepared by the biomimetic mineralization method for lysozyme immobilization via adsorption. The size and morphology of CaCO₃/CMC microspheres were characterized by transmitted electron microscopy (TEM) and zeta potential measurement. The lysozyme immobilization was verified by Fourier transform infrared (FTIR) spectroscopy. The effects of pHs and temperatures on lysozyme adsorption were investigated as well. It was revealed that CaCO₃/CMC microspheres could immobilize lysozyme efficiently via electrostatic interactions and a maximum adsorption capacity of 450 mg/g was achieved at pH 9.2 and 25 °C. Moreover, it was found that the adsorption process fitted well with the Langmuir isothermal model. In addition, UV, fluorescence, and circular dichroism (CD) spectroscopic studies showed that lysozyme maintained its original secondary structure during the adsorption/desorption process. Our study therefore demonstrated that CaCO₃/CMC microsphere can be used as a cost-effective and efficient support for lysozyme immobilization.     

Preparation and evaluation of a novel gastric mucoadhesive sustained-release acyclovir microsphere

Objective: The objective of this study was to prepare a novel gastric mucoadhesive sustained-release acyclovir (AV)-resinate microsphere. Methods: First, AV absorption ratio was quantified in a rat gastrointestinal (GI) tract model. AV-resinate was prepared by bath method and used as cores to prepare microspheres by an emulsion solvent diffusion technique with carbopol 934 as coating material. GI transit test of the prepared microspheres was carried out in rats and beagle dogs, followed by the in vivo bioavailability evaluation of the microspheres in beagle dogs. Results: The AV absorption ratio in different segments of rat's GI track for 3 hours was as following: stomach 9.46 ± 0.62%, duodenum 20.22 ± 1.50%, jejunum 15.7 ± 1.33%, ileum 9.15 ± 1.01%, and colon 4.59 ± 0.48%. These results showed that AV was mainly absorbed in the stomach and upper intestine. The average diameter of the microspheres was 115.3 μm. The microspheres had a drug content of 33.3 ± 0.7% (w/w) and a sustained-release profile for 12 hours in vitro. The mucoadhesive test in rats and beagle dogs showed that most of the microspheres were retained in the stomach 6 hours after oral administration. The in vivo pharmacokinetics test revealed that the microsphere and reference (AV tablets) preparations have no significant difference for C_max. The t_max has increased from 2.33 hours (reference) to 5 hours (test). Meanwhile, the relative bioavailability of AV microspheres was 145%. Conclusion: A novel AV-resinate microsphere was prepared. The microspheres were proved to be gastric mucoadhesive and sustained-release with higher bioavailability.     

Control of drug loading efficiency and drug release behavior in preparation of hydrophilic-drug-containing monodisperse PLGA microspheres

We prepared monodisperse poly(lactide-co-glycolide) (PLGA) microspheres containing blue dextran (BLD)—a hydrophilic drug—by membrane emulsification technique. The effects of electrolyte addition to the w₂ phase and significance of the droplet size ratio between primary (w₁/o) and secondary (w₁/o/w₂) emulsions during the preparation of these microspheres was examined. The droplet size ratio was evaluated from the effect of stirring rate of the homogenizer when preparing the primary emulsion. The drug loading efficiency of BLD in these microspheres increased with stirring rate. It increased to approximately 90% when 2.0% NaCl was added to the w₂ phase. Drug release from these microspheres was slower than that when they were prepared without electrolyte addition. Despite the very high efficiency drug release was gradual because BLD was distributed at the microspheres core. Relatively monodisperse hydrophilic-drug-containing PLGA microspheres with controlled drug loading efficiency and drug release behavior were prepared.     

Preparation of alginate–CaCl2 microspheres as resveratrol carriers

Resveratrol-loaded calcium alginate microspheres for prolonged drug release were prepared by ionic gelation of alginate with calcium chloride (CaCl₂). Further, resveratrol-loaded calcium alginate microspheres were developed using two concentrations of alginate (0.5 and 1 % w/v) and CaCl₂ (0.5 and 1 M) and an encapsulator equipped with a 300-μm nozzle. The mean particle size of the microspheres was between 175.52 and 244.03 μm, and an encapsulation efficiency (EE) of over 95 % was observed. FTIR spectroscopy indicated a polyelectrolyte interaction between alginate and CaCl₂; alginate microsphere thermograms were analyzed by differential scanning calorimetry. X-ray diffraction shows the crystalline change of microspheres by cross linking. The release profiles and EE increased depending on the CaCl₂ concentration, and a slow initial burst release was observed on freeze-dried microspheres. These results indicate that resveratrol-loaded calcium alginate microspheres can be used as a potential resveratrol delivery system in the food industry.     

Preparation and evaluation of paclitaxel-loaded nanoparticle incorporated with galactose-carrying polymer for hepatocyte targeted delivery

Objective: Paclitaxel-loaded poly(lactic-co-glycolic acid) (PLGA) nanoparticles incorporated with galactose-carrying polymer poly(vinyl benzyllactonamide) (PVLA) were prepared to facilitate the hepatocyte cell targeted delivery of paclitaxel via ligand-receptor mediated endocytosis. The factors impacting nanoparticle properties, drug release and cellular uptake efficiency were evaluated in vitro.

Method: Paclitaxel-loaded nanoparticles incorporated with PVLA were prepared by emulsion solvent evaporation method with polyvinyl alcohol (PVA) as co-emulsifier. The presence of PVLA on the particle surface was investigated through the change of ζ potential and surface hydrophobicity. Cellular uptake and cytotoxic activity, involving factors concerned with them, were evaluated by HepG2 cells in vitro.

Results: The presence of PVLA led to the increase of ζ potential, reduction of the particle surface hydrophobicity, slight promotion of paclitaxel encapsulation efficiency and more homogeneous particle size, but excessive PVLA accelerated the burst release. With enhanced attachment and cellular uptake efficiency, the PVLA incorporated nanoparticles exhibited significant cytotoxicity to HepG2 cells, and particles with higher PVLA-to-PLGA ratio, although had larger size and almost the same cellular uptake efficiency, performed much higher cytotoxic activity due to the larger drug capacity and faster release rate.     

Prolonged Release of Tegafur from S/O/W Multiple Emulsion

Abstract

To develop a prolonged and sustained release preparation, we prepared an albumin microsphere-in-oil-in-water emulsion (S/O/W) and examined sustained release from it in comparison with other control preparations such as water-in-oil (W/O) emulsions and microspheres in vitro and in vivo, respectively. Tegafur was used as a model drug. A microsphere-in-oil emulsion was prepared by adding albumin microspheres to soybean oil containing 20% Span 80. To prepare an S/O/W emulsion, the microsphere-in-oil emulsion was added into an aqueous solution of hydroxypropyl methylcellulose containing Pluronic F68. The mean particle size of the albumin microspheres was 3 µm, and the ratio of entrapment of tegafur into albumin microspheres was about 25%. In an in vitro release test, the t₇₅ of the S/O/W emulsion was fourfold greater and in an in vivo release test the mean residence time of tegafur from the S/O/W emulsion was more than twofold that from a W/O emulsion or microsphere system. The mean residence time of 5-fluorouracil (5-FU) from an S/O/W emulsion was also greater than with other dosage forms. These results suggest the possible usefulness of an S/O/W emulsion for the sustained and prolonged release of tegafur.     

Physicochemical characterization of spray-dried PLGA/PEG microspheres,and preliminary assessment of biological response

Context: The use of spray-drying to prepare blended PLGA:PEG microspheres with lower immune detection.

Objective: To study physical properties, polymer miscibility and alveolar macrophage response for blended PLGA:PEG microspheres prepared by a laboratory-scale spray-drying process.

Methods: Microspheres were prepared by spray-drying 0–20% w/w ratios of PLGA 65:35 and PEG 3350 in dichloromethane. Particle size and morphology was studied using scanning electron microscopy. Polymer miscibility and residual solvent levels evaluated by thermal analysis (differential scanning calorimetry – DSC and thermogravimetric analysis – TGA). Immunogenicity was assessed in vitro by response of rat alveolar macrophages (NR8383) by the MTT-based cell viability assay and reactive oxygen species (ROS) detection.

Results: The spray dried particles were spherical, with a size range of about 2–3?µm and a yield of 16–60%. Highest yield was obtained at 1% PEG concentration. Thermal analysis showed a melting peak at 59?°C (enthalpy: 170.61 J/g) and a degradation-onset of 180?°C for PEG 3350. PLGA 65:35 was amorphous, with a T_g of 43?°C. Blended PLGA:PEG microspheres showed a delayed degradation-onset of 280?°C, and PEG enthalpy-loss corresponding to 15% miscibility of PEG in PLGA. NR8383 viability studies and ROS detection upon exposure to these cells suggested that blended PLGA:PEG microspheres containing 1 and 5% PEG are optimal in controling cell proliferation and activation.

Conclusion: This research establishes the feasibility of using a spray-drying process to prepare spherical particles (2–3?µm) of molecularly-blended PLGA 65:35 and PEG 3350. A PEG concentration of 1–5% was optimal to maximize process yield, with minimal potential for immune detection.     

Investigation on Process Parameters Involved in Polylactide-Co-Glycolide Microspheres Preparation

Abstract

Indomethacin loaded polylactide-co-glycolide (PLGA) microspheres were prepared by emulsification solvent evaporation. The preparation involves several process parameters that can affect the morphological characteristics, the “in vitro” and “in vivo” dissolution behaviour of microspheres.

The evaluation of three process parameters, emulsification stirring rate, emulsifier concentration and dispersed phase to continuous phase ratio was carried out in order to correlate them to some microsphere properties.

Results show that the variables evaluated affect mainly microspheres drug content and, at less extent, particle size.     

In vitro evaluation of the effects of various additives and polymers on nerve growth factor microspheres

Objective: To evaluate the effects of various additives or polymers on the in vitro characteristics of nerve growth factor (NGF) microspheres.

Materials and methods: NGF microspheres were fabricated using polyethylene glycol (PEG), ovalbumin (OVA), bovine serum albumin (BSA) or glucose as protein protectors, and poly(lactide-co-glycolide) (PLGA) or poly(lactic acid) (PLA)/PLGA blends as encapsulation materials.

Results: Encapsulation efficiencies of the NGF microspheres with various additives or polymers were not more than 30%. A comparative study revealed that OVA was somewhat superior over others, and was thus chosen as the protective additive in subsequent experiments. Polymer analysis showed that NGF release from 1:1 PLA (η?=?0.8):PLGA (75/25, η?=?0.45) microspheres lasted for 90?d with a burst release rate of 12.7%. About 40% of the original bioactivity was retained on the 28th day, while 10% was left on the 90th day.

Discussion and conclusion: The combination of OVA as an additive and the PLA/PLGA blend as the coating matrix is suitable for encapsulation of NGF in microspheres for extended release.     

Preparation of Gelatin: Phenytoin Sodium Microsphers: An IN VITRO and IN VIVO Evaluation

Abstract

In this study phenytoin sodium microspheres were formulated with biodegradable acid-treated gelatin. The microspheres were subjected to in vitro and in vivo testing. The percent drug retained in the microspheres, as well as its release from the microspheres, was tested. In vitro data revealed a decrease in percent druq retained in the microspheres with an increase in addition of glutaraldehyde to the microsphere formulations. The statistically most consistent drug release was observed from formulations containing 10 g of gelatin and 2 g of phenytoin sodium. From this formulation the slowest release was observed when 5 ml of glutaraldehyde were added to the various formulations, whereas the fastest release was observed when no glutaraldehyde was added. In vivo studies consisted of administering phenytoin sodium in microsphere form and an aqueous solution v i a various routes of administration and determining phenytoin plasma concentration vs. time profiles in female Sprague Dawley Rats. Computer fitting of the in vivo data and subsequent statistical testing enabled comparison of the effect of microsphere formation and the effect of microsphere dose on selected pharmacokinetic parameters.     

Development and characterization of wheat gluten microspheres for use in a controlled release system

The purpose of this study was the development and characterization of wheat gluten microspheres for use as controlled release devices, and the evaluation of the effect of the addition of poly (ethylene glycol) (PEG). Diltiazem hydrochloride was used as the model drug in the in vitro release essay. The physical–chemical and morphological properties of the microspheres were evaluated, as well as their encapsulation efficiency. Porosity varied with the presence or absence of PEG. The diltiazem encapsulation efficiency was 72.8% and 96.7% for wheat gluten and gluten/PEG 95/05 microspheres, respectively. The DSC and FTIR results indicated interactions between the microparticles and additives used. In the in vitro release tests it was observed that, for all the studied systems, the burst effect occurred in the first 2 h of release and the microspheres prepared with PEG had a faster release rate. In the attempt to elucidate the release mechanism, the systems were treated based on two well known mathematical models: the Higuchi and the power law. It was found that the microsphere release mechanism is not exclusively diffusion-controlled and, probably, the release occurs through a combination of partial diffusion through the swelling matrix and hydrophilic pores.     

Colorectal cancer targeted Irinotecan-Assam Bora rice starch based microspheres: a mechanistic,pharmacokinetic and biochemical investigation

The purpose of this investigation was to evaluate the colon-targeted Irinotecan Hydrochloride (ITC-HCl) loaded microspheres by pharmacokinetic and biochemical studies. The microspheres were prepared by double emulsion solvent evaporation method with natural polymer Assam Bora rice starch. The microspheres were characterized for their micromeritics properties, incorporation efficiency, in vitro and in vivo drug release studies. The release study confirmed the insignificant release of ITC-HCl in physiological condition of stomach and small intestine and major drug release in the caecal content. In vivo release study of the optimized microsphere was compared with immediate release (IR) ITC-HCl. ITC-HCl was distributed predominantly in the upper GI tract from the IR, whereas ITC-HCl was distributed primarily to the lower part of GI tract from the microspheres formulation. Enhanced levels of liver enzymes were found in animals given IR ITC-HCl as well as augmented levels of serum albumin, creatinine, leucocytopenia and thrombocytopenia was also observed. In summary, Assam Bora rice starch microspheres exhibit slow and extended release of ITC-HCl over longer periods of time with reduced systemic side-effects.     

Nanosponge-based pediatric-controlled release dry suspension of Gabapentin for reconstitution

Abstract

Context: Gabapentin was selected to formulate oral controlled release dry suspension because of short biological half life of 5–7?h and low bioavailability (60%). Gabapentin is a bitter drug so an attempt was made to mask its taste.

Objective: To formulate and evaluate controlled release dry suspension for reconstitution to increase the bioavailability and to control bitter taste of drug.

Materials and methods: Cyclodextrin based nanosponges were synthesized by previously reported melt method. The nanosponge–drug complexes were characterized by FTIR, DSC and PXRD as well as evaluated for taste and saturation solubility. The complexes were coated on Espheres by a suspension layering technique followed by coating with ethyl cellulose and Eudragit RS-100. A dry powder suspension for reconstitution of the microspheres was formulated and evaluated for taste, redispersibility, in vitro dissolution, sedimentation volume, leaching and pharmacokinetics.

Results and discussion: The complexes showed partial entrapment of drug nanocavities. Significant decrease in solubility (25%) was observed in the complexes than pure drug in different media. The microspheres of nanosponge complexes showed desired controlled release profile for 12?h. Insignificant drug leaching was observed in reconstituted suspension during storage for 7 days at 45?°C/75% RH. Nanosponges effectively masked the taste of Gabapentin and the coating polymers provided controlled release of the drug and enhanced taste masking. The results of in vivo studies showed increase in bioavailability of controlled release suspension by 24.09% as compared to pure drug.

Conclusion: The dry powder suspension loaded with microspheres of nanosponges complexes can be proposed as a suitable controlled release drug delivery for Gabapentin.     

Poly(lactide-co-glycolide) encapsulated hydroxyapatite microspheres for sustained release of doxycycline

The purpose of this study was to prepare a poly(lactide-co-glycolide) (PLGA) encapsulated hydroxyapatite microspheres (HAP-MSs) as injectable depot for sustained delivery of Doxycycline (Doxy). Doxy loaded HAP-MSs (Doxy-HAP-MSs) were encapsulated with PLGA by solid-in-oil-in-water (S/O/W) emulsion-solvent evaporation technique, the effects of the PLGA used (various intrinsic viscosity and LA/GA ratio) and ratio of PLGA/HAP-MSs on the formation of Doxy-HAP-MSs and in vitro release of Doxy were studied. The results showed that sustained drug release without obvious burst was obtained by using PLGA encapsulated HAP-MSs as the carrier, also the drug release rate could be tailored by changing the ratio of PLGA/HAP-MSs, or PLGA of various intrinsic viscosities or LA/GA ratio. Lower ratio of PLGA/HAP-MSs corresponded faster Doxy release, e.g. for the microspheres of PLGA/HAP-MSs ratio of 8 and 0.25, the in vitro Doxy release percents at the end of 7days were about 23% and 76%, respectively. Higher hydrophilicity (higher ratio of GA to LA) and lower molecular weight of PLGA corresponded to higher Doxy release rates. For in vivo release study, PLGA encapsulated HAP-MSs were subcutaneously injected to the back of mice, and the results showed good correlation between the in vivo and in vitro drug release. Meanwhile, the plasma Doxy levels after subcutaneous administration of PLGA encapsulated Doxy-HAP-MSs were relatively lower and steady compared to that of the un-encapsulated microspheres. In conclusion, PLGA encapsulated HAP-MSs may be a potential vehicle for the sustained delivery of Doxy.     

Double-walled microspheres loaded with meglumine antimoniate: preparation,characterization and in vitro release study

Objective: The objective of this study was to fabricate double-walled poly(lactide-co-glycolide) (PLGA) microspheres to increase encapsulation efficiency and avoid rapid release of hydrophilic drugs such as meglumine antimoniate.

Methods: In this study, double-walled and one-layered microspheres of PLGA were prepared using the emulsion solvent evaporation technique to better control the release of a hydrophilic drug, meglumine antimoniate (Glucantime®), which is the first choice treatment of cutaneous leishmaniasis. The effect of hydrophobic coating on microspheres' size, morphology, encapsulation efficiency and drug release characteristics was evaluated. Furthermore, the presence of antimony in meglumine antimoniate made it possible to observe the drug distribution within the microspheres' cross section by means of energy dispersive X-ray spectroscopy.

Results: Drug distribution images confirmed accumulation of the drug within the inner core of double-walled microspheres. In addition, these microspheres encapsulated the drug more efficiently up to 87% and demonstrated reduced initial burst and prolonged release compared to one-layered microspheres. These superiorities make double-walled microspheres an optimum candidate for sustained delivery of hydrophilic drugs.

Conclusion: Double-walled microspheres provide some advantages over traditional microspheres overcoming most of their limitations. Double-walled microspheres were found to be more efficient than their corresponding one-layered microspheres in terms of encapsulation efficiencies and release characteristics.