In vitro controlled release of bupivacaine from albumin microspheres and a co-matrix formed by microspheres in a poly(lactide-co-glycolide) film

Albumin microspheres cross-linked with glutaraldehyde and loaded with bupivacaine, a local anaesthetic, were synthesized (138 +/- 59 microm diameter). A matrix formed by bupivacaine-loaded microspheres in a poly(lactide-co-glycolide) film was prepared in order to improve the controlled release of the drug. In vitro release of the drug was determined in phosphate buffer at 37 degrees C in the absence and in the presence of protease type VIII to mimic a biological system. The effect of temperature and protease on bupivacaine as a function of time was examined; both of them cause a degradative effect on the drug. A rapid release (60 +/- 8% of the drug) takes place at 1 h, and maximum release is found at 50 +/- 6 h from microspheres with swelling. In the presence of protease, maximum release of bupivacaine from microspheres is found at 28 +/- 2 h; the microspheres disappear at 8 days. Inclusion of bupivacaine-loaded microspheres in a poly(lactide-co-glycolide) film causes a slower release of the drug, up to 18 days, with swelling. In the presence of protease, the polymer protects bupivacaine-loaded microspheres from degradation, which takes place at 20 days.     

Spray-dryed bupivacaine-loaded microspheres: in vitro evaluation and biopharmaceutics of bupivacaine following brachial plexus administration in sheep

Microspheres could be used as a drug delivery system to prolong the duration of action of bupivacaine and to reduce its systemic absorption leading to high plasma concentrations related to central nervous and cardiovascular toxicity. Bupivacaine-loaded microspheres were made by spray-drying using polylactide-co-glycolide polymers from different sources and with different bupivacaine-polymer ratio. The characterization of microspheres concerned the shape and size, the bupivacaine drug-content (DC) and the cumulative release profiles. We evaluated in sheep the bupivacaine pharmacokinetics: (i) after short intravenous infusion of 75 mg bupivacaine solution; and (ii) following brachial nerve plexus injections of 75 mg bupivacaine solution alone, with the addition of 75 microg epinephrine, with the addition of 150 microg epinephrine and of bupivacaine (750 mg)-loaded microspheres. Release profiles showed a biphasic pattern whatever the DC. After i.v. infusion the mean clearance value was 1.53+/-0.53 l/min and the mean elimination half-life was 120.5+/-73.1 min. Following brachial plexus nerve injection, bupivacaine C(max) were lower than 100 ng/ml following either solution or microspheres administration. Ninety percent of the 75 mg bupivacaine given as a solution were absorbed in 5.8+/-1.0 h (bupivacaine alone) compared to 24.6+/-1.2 h following microsphere administration.     

5-Fluorouracil plasma levels and biodegradation of subcutaneously injected drug-loaded microspheres prepared by spray-drying poly(D,L-lactide) and poly(D,L-lactide-co-glycolide) polymers

Microspheres (MS) of 5-fluorouracil-loaded poly(D,L-lactide) (PLA), poly(D,L-lactide-co-glycolide) 75/25 (PLGA 75/25) and poly(D,L-lactide-co-glycolide) 50/50 (PLGA 50/50) prepared by the spray-drying technique were subcutaneously injected in the back of Wistar rats in order to evaluate the 5-fluorouracil (5-FU) release and the biodegradation characteristics. Determination of plasma 5-FU concentration by HPLC with analysis of data using a non-compartmental model showed drug in plasma between 9 and 14 days after administration of drug-loaded PLGA 50/50 or PLA and PLGA 75/25 microspheres, respectively, with a maximum drug concentration of 2.4+/-0.2microg/mL at 24h (5-FU-loaded PLGA 50/50 MS), 2.5+/-0.1microg/mL at 48h (5-FU-loaded PLGA 75/25 MS), and 2.3+/-0.1microg/mL at 24h (5-FU-loaded PLA MS). Pharmacokinetically, a significant increase of AUC (up to 50 times) and MRT (up to 196 times) of 5-FU with regard to the administration of the drug in solution was observed. Scanning electron microscopy and histological studies indicated that a small fibrous capsule was observed around the microspheres in the site of injection. One month after the injection of PLGA 50/50 MS and 2 months after the injection of PLGA 75/25 and PLA MS, masses of polymers, instead of single microspheres, were observed. Close to them, macrophagic cells were present, and blood vessels were observed in the connective tissue. Total absence of fibrous capsule and injected microspheres was observed after 2 (for PLGA 50/50 MS) or 3 (PLGA 75/25 and PLA MS) months.     

Chitosan microspheres in PLG films as devices for cytarabine release

Cytarabine was included in chitosan microspheres and several of these microspheres were embedded in a poly(lactide-co-glycolide) (PLG) film to constitute a comatrix system, to develop a prolonged release form. Chitosan microspheres, in the range of 92+/-65 microm, having good spherical geometry and a smooth surface incorporating cytarabine, were prepared. The cytarabine amount included in chitosan microspheres was 43.7 microg of ara-C per milligram microsphere. The incorporation efficiency of the cytarabine in microspheres was 70.6%. Total cytarabine release from microspheres in vitro was detected at 48 h. Inclusion of cytarabine-loaded microspheres in poly(lactide-co-glycolide) film initiated a slower release of the drug and, in this way, the maximum of cytarabine released (80%) took place in vitro at 94.5 h. Comatrices, with 8.7 mg of cytarabine, signifying a dose of 34.5 microg/kg, were subcutaneously implanted in the back of rats. Maximum plasma cytarabine concentration was 18.5+/-1.5 microg/ml, 48 h after the device implantation and the drug was detected in plasma for 13 days. The histological studies show a slow degradative process. After 6 months of implantation, most of the microspheres of the matrix seemed to be intact, the comatrix appeared surrounded by conjunctive tissue and small blood vessels and nerve packets were detected in the periphery of the implant.     

Cytarabine release from comatrices of albumin microspheres in a poly(lactide-co-glycolide) film: in vitro and in vivo studies.

Cytarabine (ara-C) was included in albumin microspheres and these microspheres were immersed in a poly(lactide-co-glycolide) (PLGA) film to constitute a comatrix system to develop a prolonged form of release. Cytarabine-loaded albumin microspheres were synthesized by emulsion, and 25 or 50 mg of drug were included in the disperse phase. Thus, microspheres with 46+/-4 microg drug/mg microspheres and 50+/-5 microg drug/mg microspheres were obtained, which means a percentage of incorporation efficiency of 42+/-4% and 25+/-2%, respectively. These cytarabine-loaded microspheres were used to prepare PLGA-comatrices. Kinetic release studies indicated that total cytarabine release only takes place in the presence of protease, probably due to the fact that glutaraldehyde establishes covalent links with the amine side group of the drug and cross-links it with the protein matrix. A slower kinetic release of the drug was obtained from PLGA-comatrices, although only 80% of the included cytarabine was released on day 7. The comatrices were subcutaneously implanted in the back of rats and in both cases the ara-C administered dose was 36 mg of ara-C per kg of body weight. The drug was detected in plasma 10 days. The mean residence time (MRT) of the drug administered by these comatrices was 87-91 times larger when compared to the value obtained when the drug was administered in solution by intraperitoneal injection. The histological studies show that a degradative process of the comatrices takes place. The comatrices do not damage surrounding tissue; a normal regeneration of the implanted zone was observed.     

Ketotifen-loaded microspheres prepared by spray-drying poly(D,L-lactide) and poly(D,L-lactide-co-glycolide) polymers: characterization and in vivo evaluation

Ketotifen (KT) was encapsulated into poly(D,L-lactide) (PLA) and poly(D,L-lactide-co-glycolide) (PLGA 50/50) by spray-drying to investigate the use of biodegradable drug-loaded microspheres as delivery systems in the intraperitoneal cavity. Ketotifen stability was evaluated by HPLC, and degradation was not observed. Drug entrapment efficiency was 74 +/- 7% (82 +/- 8 microg KT/mg for PLA) and 81 +/- 6% (90 +/- 7 microg KT/mg for PLGA 50/50). PLA microspheres released ketotifen (57% of encapsulated KT) in 350 h at two release rates (221 microg/h, 15 min to 2 h; 1.13 microg/h, 5-350 h). A quicker release of ketotifen took place from PLGA 50/50 microspheres (67.4% of encapsulated KT) in 50 h (322 microg/h, 15 min to 2 h; 16.18 microg/h, 5-50 h). After intraperitoneal administration (10 mg KT/kg b.w.), microsphere aggregations were detected in adipose tissue. Ketotifen concentration was determined in plasma by HPLC. The drug released from PLA and PLGA 50/50 microspheres was detected at 384 and 336 h, respectively. Noncompartmental analysis was performed to determine pharmacokinetic parameters. The inclusion of ketotifen in PLGA and PLA microspheres resulted in significant changes in the plasma disposition of the drug. Overall, these ketotifen-loaded microspheres yielded an intraperitoneal drug release that may be suitable for use as delivery systems in the treatment of inflammatory response in portal hypertension.     

Kinetic and dynamic studies of liposomal bupivacaine and bupivacaine solution after subcutaneous injection in rats

The pharmacodynamics and pharmacokinetics of bupivacaine in solution and in liposome preparations following subcutaneous administration were studied in rats. Multilamellar vesicles entrapping bupivacaine solution were prepared. The local anaesthetic effect was estimated by the tail-flick test in Wistar rats treated with 1 mg bupivacaine in 0.2-mL preparations. Plasma concentrations of bupivacaine were determined by high-performance liquid chromatography. The results showed that both bupivacaine solution and bupivacaine liposomes revealed local anaesthetic effects in the initial tail-flick test (15 min after injection). With bupivacaine liposomes, the duration of action was 5-fold (447+/-28.9 vs 87+/-6.7 min), the maximum possible effect was 2-fold (100+/-0 vs 47.6+/-13%), and the peak plasma concentration (Cmax) was less than one-fifth (0.12+/-0.04 vs 0.65+/-0.04 microg mL(-1)) that with bupivacaine solution. The sensory block effect of bupivacaine solution completely resolved at 90 min, while the plasma concentration of bupivacaine was still more than half the Cmax. Bupivacaine liposomes resulted in a low and relatively constant plasma level (approx. 0.1 microg mL(-1)) and a pronounced local anaesthetic effect throughout the experimental period (> 7 h). In conclusion, bupivacaine liposomes elevated the intensity and prolonged the duration of the local anaesthetic effect of bupivacaine, and suppressed the systemic absorption rate of encapsulated bupivacaine.     

Determination of local tissue concentrations of bupivacaine released from biodegradable microspheres and the effect of vasoactive compounds on bupivacaine tissue clearance studied by microdialysis sampling

Purpose. Incorporation of bupivacaine, a short acting local analgesic, into injectable microspheres provides a long acting formulation. Co-incorporation of dexamethasone into the microspheres results in extended activity. The purpose of this study is to compare tissue concentrations of bupivacaine resulting from the two types of microspheres and to determine if the observed sustained tissue concen- tration of bupivacaine is due to changes in its tissue clearance. Methods. Microdialysis probes were implanted into rat muscle. Following microsphere injection, bupivacaine tissue concentration was monitored (HPLC-UV), and the tissues histologically examined. The effect of vasoactive compounds on the tissue concentration of bupivacaine, not formulated in microspheres, was monitored. Results. Hind muscle histology showed significant granulomatous reactions around the probe and both types of microspheres. A higher, prolonged bupivacaine concentration was observed from microspheres. A higher, prolonged bupivacaine concentration was observed from microspheres with co-incorporated dexamethasone relative to those without dexamethasone. Addition of vasoconstrictors to the perfusate containing bupivacaine resulted in decreased bupivacaine delivery compared to bupivacaine alone, whereas the addition of a vasodilator increased bupivacaine delivery. Conclusions. The longer lasting effect of microspheres with co-incorporated dexamethasone results from higher, prolonged tissue concentrations of bupivacaine. Dexamethasone, a vasoconstrictor, decreases the clearance rate of bupivacaine from the tissue resulting in a higher, prolonged tissue concentration of bupivacaine.     

Steady state bupivacaine plasma concentrations and safety of a femoral "3-in-1" nerve block with bupivacaine in patients over 80 years of age

OBJECTIVES: Fracture of the upper femur is a common injury in the elderly. Several anesthetic techniques exist for surgery of traumatic hip fracture. The aim of this investigation was to study plasma concentrations and safety of 2 mg/kg bupivacaine in a femoral "3-in-1" nerve block in patients older than 80 years of age. SUBJECTS AND METHODS: A 3-in-1 femoral nerve block, combined with a general anesthetic was used in 10 elderly patients aged over 80 years. They were undergoing emergency surgery for stabilization of their fractured femur. Bupivacaine plasma concentrations of radial artery blood samples were assessed over a 6-hour period after a femoral 3-in-1 injection of 2 mg/kg bupivacaine 0.375% with epinephrine (1:400,000). RESULTS: No toxic reactions to bupivacaine were seen. In 8 of the 10 patients per- and postoperative analgesia were adequate as a result of the nerve block. Patients experienced loss of sensation and analgesia for 26.6 +/- 4.6 hours (mean +/- SD). This was inversely related to the apparent steady state concentration of bupivacaine. The mean of the individual peak plasma concentrations of bupivacaine (C(max) was 0.74+/- 0.64 microg/ml. The highest plasma concentration was 1.83 microg/ml. Large variations in plasma concentrations were detected in these patients. Bupivacaine metabolites were not detected. CONCLUSIONS: A femoral 3-in-1 nerve block, using 2 mg/kg bupivacaine with epinephrine, provides prolonged pain reliefwithout local anesthetic toxicity in elderly patients. It is a satisfactory supplementary analgesic technique for hip and knee surgery in the elderly.     

A new method for studying the distribution of drugs in spinal cord after intrathecal injection

The pharmacological effect of local anaesthetic solutions in mice including their distribution within the spinal cord, were assessed following intrathecal injection at the L5-L6 interspace. A solution of 5 microliters radioactively labelled lidocaine at a concentration of 50 mg/ml or bupivacaine at 7.5 mg/ml, was used. Both drugs blocked the motor function of the hindlegs in less than 1 min. This persisted for 15.1 +/- 0.8 min. (mean +/- S.E.M.) after lidocaine and 15.2 +/- 2.7 min. after bupivacaine. The highest spinal cord concentration was adjacent to the site of injection, even if traces were present up to the lower cervical cord. The tissue concentration of bupivacaine was considerably less than that of lidocaine, despite a similar motor blockade. When the injected volume was doubled from 5 to 10 microliters, there was a tendency to a more cephalic distribution of lidocaine. When the speed of injection was increased from 2.5 sec., to 30 sec., no difference in results was seen. The drug concentration at the injection site tended to fall in animals alive until 5 min. after the injection, whereas it persisted in animals sacrificed before the intrathecal injection, suggesting that the circulatory transport is the major route of redistribution from the cord.     

Intra-articular lornoxicam loaded PLGA microspheres: enhanced therapeutic efficiency and decreased systemic toxicity in the treatment of osteoarthritis

The aim of this study was to investigate the joint tissue distribution and pharmacodynamics of Lornoxicam (Lnxc) following intra-articular injection of either Lnxc suspensions or sustained release Lnxc-loaded PLGA microspheres (Lnxc-MS), as well as the biocompatibility of PLGA microspheres with or without drugs. In this study, Lnxc suspensions or Lnxc-loaded PLGA microspheres was injected into the knee joint cavity of rats. Blood samples were taken at predetermined times from the jugular vein and the joint tissue (cartilage and synovial membrane) were removed from the rats. Biocompatibility and pharmacodynamics were evaluated by observing the swelling of the joints of the rats and histological analysis following the injection of the microspheres. The plasma drug concentration decreased in rats and retention time increased in rats' joint with intra-articular injections of microspheres, revealing good targeting efficiency and decreased systemic toxicity. After 30 days of intra-articular injection with Lnxc-loaded or blank microspheres, the filtration liquid accumulation, blood vessels and fibrous proliferation were not detected, showing their good compatibility. Furthermore, the articular cartilage damage by papain could also be repaired by the Lnxc-loaded PLGA microspheres. In conclusion, intra-articular Lnxc-MS have considerable potential for creating a sustained release Lnxc delivery system and providing effective healing to Osteoarthritis.     

Intra-articular lornoxicam loaded PLGA microspheres: enhanced therapeutic efficiency and decreased systemic toxicity in the treatment of osteoarthritis

The aim of this study was to investigate the joint tissue distribution and pharmacodynamics of Lornoxicam (Lnxc) following intra-articular injection of either Lnxc suspensions or sustained release Lnxc-loaded PLGA microspheres (Lnxc-MS), as well as the biocompatibility of PLGA microspheres with or without drugs. In this study, Lnxc suspensions or Lnxc-loaded PLGA microspheres was injected into the knee joint cavity of rats. Blood samples were taken at predetermined times from the jugular vein and the joint tissue (cartilage and synovial membrane) were removed from the rats. Biocompatibility and pharmacodynamics were evaluated by observing the swelling of the joints of the rats and histological analysis following the injection of the microspheres. The plasma drug concentration decreased in rats and retention time increased in rats’ joint with intra-articular injections of microspheres, revealing good targeting efficiency and decreased systemic toxicity. After 30 days of intra-articular injection with Lnxc-loaded or blank microspheres, the filtration liquid accumulation, blood vessels and fibrous proliferation were not detected, showing their good compatibility. Furthermore, the articular cartilage damage by papain could also be repaired by the Lnxc-loaded PLGA microspheres. In conclusion, intra-articular Lnxc-MS have considerable potential for creating a sustained release Lnxc delivery system and providing effective healing to Osteoarthritis.     

Preparation andin vivo evaluation of huperzine A-loaded PLGA microspheres

Huperzine A-loaded microspheres composed of poly(D,L-lactide-co-glycolide) were prepared by an ONV emulsion solvent evaporation method. The characterization of the microspheres such as drug loading, size, shape and release profile was described. The in vitro release in the initial 7 days was nearly linear with 10% released per day. Thereafter drug release rate became slow gradually and about 90% drug released at day 21. The in vitro release rate determined by dialysis bag method had a good correlation with the in vivo release rate. Huperzine A aqueous solution was intramuscularly injected (i.m.) at 0.4 mg/kg and microspheres were intramuscularly injected at 8.4 mg eq huperzine A/kg in rats. The maxium plasma concentration (Cmax ) after i.m. microspheres was only 32% of that after i.m. solution. Drug in plasma could be detected until day 14 and about 5% of administered dose was residued at the injection site at day 14. The relative bioavailability of huperzine A microspheres over a period of 14 days was 94.7%. Inhibition of acyecholinesterase activity (AchE) in rat's cortex, hippocampus and striatum could sustain for about 14 days. In conclusion, huperzine A-loaded microspheres possessed a prolonged and complete drug release with significant inhibition of AchE for 2 weeks in rats.     

Stability of fentanyl citrate and bupivacaine hydrochloride in portable pump reservoirs

The stability of fentanyl citrate and bupivacaine hydrochloride in an admixture with 0.9% sodium chloride injection in portable pump reservoirs with or without overwraps was investigated. Twelve 100-mL samples containing fentanyl 20 micrograms/mL and bupivacaine hydrochloride 1250 micrograms/mL were placed in the plastic drug reservoirs, and 1-mL quantities were withdrawn immediately after preparation and at intervals during 30 days of storage. Six reservoirs were refrigerated (3 degrees C) and six stored at room temperature (23 degrees C); three at each temperature were placed in overwraps. All samples were observed for precipitation and for change in color or pH and were analyzed for drug concentration by high-performance liquid chromatography. No precipitation or change in color or pH was observed during the 30-day storage period. No loss of fentanyl or bupivacaine was detected in either the wrapped or the unwrapped samples. Fentanyl citrate and bupivacaine hydrochloride in 0.9% sodium chloride injection appear to be compatible, and admixtures containing the two drugs at the concentrations studied can be stored without overwraps for up to 30 days at refrigerated or room temperature without any significant loss of potency.     

布比卡因缓释微球的制备及体外释药特性评价

目的研究布比卡因缓释微球制备方法并对其体外释药特性进行评价。方法采用紫外分光光度法测定布比卡因微球载药量、包封率;采用HPLC法测定微球体外释放;通过正交设计优选微球制备工艺;以乳酸羟基乙酸共聚物为载体,使用乳化溶剂挥发法制备布比卡因微球;用扫描电镜观察所得微球的粒径和形态;通过体外释药实验考察布比卡因乳酸羟基乙酸共聚物微球的缓释作用。结果微球载药量、包封率和体外释放的测定方法符合方法学要求;按照优选处方制备所得的微球为圆整球体,表面多孔,呈蜂窝状,粒径50~100μm之间的微球占80%;体外释放符合Ritger-Peppas方程,t1/2=242.05 h。结论乳化溶剂挥发法适用于布比卡因乳酸羟基乙酸共聚物微球的制备,所制得的微球形态圆整,在体外具有明显缓释作用。     

Preparation and in vivo evaluation of thienorphine-loaded PLGA microspheres

Thienorphine-loaded microspheres composed of poly(D,L-lactide-co-glycolide) were prepared by an O/W emulsion solvent evaporation method. HPLC was used to determine the drug loading and drug release, while a LC-MS-MS system was employed to analyze the plasma drug concentration. Results indicated that the PLGA particles obtained were spherical and of appropriate size. The formulation was stable during the test period. In vitro drug release from the microspheres was sustained for about 28 days mostly by the diffusion mechanism. The plasma drug concentration-time profiles were relatively smooth for about 28 days after subcutaneous injection of the drug-loaded microspheres to rats, compared with that for drug suspension. In vitro and in vivo correlation was established.     

Characterization of biodegradable chitosan microspheres containing vancomycin and treatment of experimental osteomyelitis caused by methicillin-resistant Staphylococcus aureus with prepared microspheres

The biodegradable chitosan microspheres containing vancomycin hydrochloride (VANCO) were prepared by spray drying method with different polymer:drug ratios (1:1, 2:1, 3:1 and 4:1). Thermal behaviour, particle size and distribution, morphological characteristics, drug content, encapsulation efficiency, in vitro release assessments of formulations have been carried out to obtain suitable formulation which shows sustained-release effect when implanted. Sterilized VANCO loaded microspheres were implanted to proximal tibia of rats with methicillin-resistant Staphylococcus aureus (MRSA) osteomyelitis. Intramuscular (IM) injection of VANCO for 21 days was applied to another group for comparison. After 3 weeks of treatment, bone samples were analysed with a microbiological assay. According to the results, encapsulation efficiency and yield of microspheres in all formulations were higher than 98% and 47%, respectively. Particle sizes of microspheres were smaller than 6 microm. All microsphere formulations have shown sustained-release effect. In vitro drug release rate decreased due to the increase in polymer:drug ratio but no significant difference was seen between these results (p>0.05). Based on our in vivo data, rats implanted VANCO-loaded chitosan microspheres and administered IM injection showed 3354+/-3366 and 52500+/-25635 colony forming unit of MRSA in 1g bone samples (CFU/g), respectively. As a result, implanted VANCO-loaded microspheres were found to be more effective than IM route for the treatment of experimental osteomyelitis.     

Central nervous system kinetics of atenolol and metoprolol in the dog during long term treatment

Beagle dogs with catheters chronically implanted into the lateral cerebral ventricle were used to study the distribution of atenolol and metoprolol between the cerebrospinal fluid (CSF) and blood plasma over a 24-hr period during long term treatment. The concentration of atenolol declined more slowly in CSF than in blood plasma and the CSF/plasma ratio of atenolol (after iv administration for 7 days) increased from 0.08 +/- 0.02 (2 hr after dose) to 0.83 +/- 0.14 (24 hr after dose) (mean +/- SD). Furthermore, the CSF concentration of atenolol, relative to the plasma concentration, increased during repeated drug administration. The CSF/plasma ratio 24 hr after an iv dose was 0.48 +/- 0.12 on day 1 and 0.83 +/- 0.14 on day 7. The CSF concentration of the more lipophilic beta 1-adrenoceptor antagonist metoprolol was almost the same as the concentration of the drug in blood plasma. After 7 days of oral treatment, the CSF/plasma ratio of metoprolol 24 hr after dosing was 0.81 +/- 0.10. The regional CSF concentration of atenolol along the neuraxis was determined in anaesthetized dogs after acute iv administration of the drug. The atenolol concentration in CSF from the lateral cerebral ventricle was similar to that in the cisterna magna but lower than the concentration in CSF sampled from the lumbar region. It is concluded that the CSF concentration of the moderately lipophilic beta 1-adrenoceptor antagonist metoprolol equilibrates with the plasma concentration of the drug more rapidly compared with the hydrophilic drug atenolol.     

Augmentation of all‐trans‐retinoic acid concentration in plasma by preventing inflammation responses induced by atRA‐loaded microspheres with concurrent treatment of dexamethasone

All‐trans retinoic acid (atRA)‐loaded microspheres severely induce inflammatory responses after microsphere implantation. Fibroblasts and a thick band of fibrous capsule resulting from the inflammatory responses could hamper drug permeation to the bloodstream because fibroblasts actively metabolize atRA into polar metabolites and the thick fibrous capsule acts as a diffusion barrier. In the present study, we investigated whether the fibroblast proliferation and collagen deposition induced by atRA released from microspheres might affect the atRA concentration in plasma and atRA metabolism with or without treatment of dexamethasone as an anti‐inflammatory drug. After subcutaneous injection of atRA‐loaded microspheres in rats, it was observed that atRA‐loaded microspheres induced severe inflammatory responses and stimulated fibroblast proliferation and collagen deposition in fibrous capsules. On the other hand, the orally treated dexamethasone effectively prevented inflammatory responses in a dose‐dependent manner and suppressed about 49% of the number of fibroblasts and collagen deposition in fibrous capsules at 14 days. In addition, after the treatment of dexamethasone, the atRA concentration in plasma was increased, and its metabolism was decreased approximately by 40% at 7 days, compared to the group treated alone with atRA‐loaded microspheres. In conclusion, the concurrent treatment of dexmethasone with atRA‐loaded microspheres could prevent inflammatory responses and metabolism of atRA, thereby maintaining the atRA concentration in plasma for longer periods in the therapeutic range. Drug Dev. Res. 61:197–206, 2004. © 2004 Wiley‐Liss, Inc.     

Bupivacaine-loaded biodegradable poly(lactic-co-glycolic) acid microspheres I. Optimization of the drug incorporation into the polymer matrix and modelling of drug release

Bupivacaine has been encapsulated by solvent evaporation method based on O/W emulsion, using poly(DL-lactic-co-glycolic) acid (PLGA) 50:50. The particle size can be controlled by changing stirring rate and polymer concentration. The encapsulation efficiency was affected by polymer concentration and burst effect of bupivacaine released from particles was affected by drug/polymer mass ratio. Orthogonal design was used to optimize the formulation according to drug content, encapsulation efficiency and burst effect. The dissolution profile and release model were evaluated with two different bupivacaine microspheres (bupi-MS) groups including low drug loading (6.41%) and high drug loading (28.92%). It was observed that drug release was affected by drug loading especially the amount of drug crystal attached on surface of bupi-MS. The drug release profile of low drug loaded bupi-MS agreed with Higuchi equation and that of high drug loaded bupi-MS agreed with first order equation.