贝尼尔聚乳酸微球缓释制剂的制备方法解析

文章根据单因素设计的要点，通过溶剂挥发的方式综合研究微球载药量，从具体微球粒径大小入手设计贝尼尔聚乳酸微球缓释制剂的制备方法。重点阐述如何制备贝尼尔聚乳酸微球缓释制剂，首先分析贝尼尔聚乳酸微球缓释制剂的制备思路，然后从制剂材料载药量的影响、制剂制备的稳定性、制剂制备质量几个方面深入说明并探讨贝尼尔聚乳酸微球的制备效果，全面总结和归纳制备贝尼尔聚乳酸微球缓释制剂的要点，强化制剂制备的综合效益，希望能为相关研究提供条件支持。     

一种白细胞介素 -12 缓释微球制备及体外表征

目的:开发一种白细胞介素-12(IL-12)长效缓释微球剂型。方法:采用水包油-油包固(S/O/W)法制备了白介素-12因子多糖微粒的聚乳酸-聚羟基乙酸共聚物(PLGA-PLA)微球,研究了微球的表面形态和粒径大小,并且运用ELISA方法考察了微球的体外释放效果和免疫活性。结果:本方法制备的白介素-12因子微球光滑圆整,体外缓释达45天,累积释放率近90%。结论:本方法制备的白介素-12因子微球,不仅具有有效地保护IL-12蛋白活性,同时实现长效缓释的目标,是一种可行的IL-12缓释方案。     

胶原酶缓释微球的研究

目的:本实验旨在开发一种胶原酶缓释微球制剂,用以治疗手掌腱膜挛缩症,以减小现有水针剂的不足。方法:利用水相-水相乳化法和低温冷冻相分离法两种方法制备载药颗粒,分别将其包裹于PLGA微球内,制备成胶原酶微球,并用扫描电镜考察其表面形态,对其粒径进行统计学分析,测定体外释放行为并比较。结果:两种方法制备的微球表面光滑圆整,都可以达到缓释的效果,一个星期内释药完全。水相-水相乳化法制备的微球比低温冷冻相分离制备的微球粒径大,且具有统计学差异(P0.05)。水相-水相乳化法制备的微球粒径较均一,其体外释放更加平缓,突释较小。结论:本研究制得的胶原酶微球能实现理想的体外缓释效果,解决了现有技术中胶原酶粉针剂型快速释放并分散的问题。     

一种新型的基因传递系统:PLGA微球

乳酸聚乙醇酸是一类可生物降解的高分子聚合材料,通过其自身降解来调节药物释放．具有良好的生物相容性。包裹或吸附药物而制成的微球多用于药物的缓释给药系统,近几年来将这一系统应用于包裹基因。该文介绍乳酸聚乙醇酸基因微球的制备方法、主动脱逸特性等。     

装载于PLGA中的5-氟尿嘧啶缓释微球的制备及其体外释放的研究

目的：研究装载于不同分子量的PLGA中的5-氟尿嘧啶微球的制备方法及其在体外条件下的缓释行为。方法：以水包油包固复乳法将5-氟尿嘧啶包裹在高分子聚乳酸-聚羟基乙酸共聚物（PLGA）中,形成缓释微球,考察其大小,外观,包封率等理化性质,以紫外分光光度法为检测方法研究其体外释放行为。结果：经扫描电子显微镜观察,所制备的微球形态完整,大小较均匀。具有一定得包封率和载药量,体外释放研究表明其处方1和处方2的缓释时间为8天和23天。结论：以水包油包固复乳法制备的PLGA 5-氟尿嘧啶微球能够达到缓释的目的。     

可控性释放NGF的京尼平- 壳聚糖微球的研究

目的:在体外研究京尼平-壳聚糖微球可控性释放具有生物活性的神经生长因子的可行性。方法:采用"乳化-化学交联"技术制备包埋神经生长因子的京尼平-壳聚糖微球,京尼平为化学交联剂;应用扫描电镜、粒径分布、体外缓释动力学及细胞生物活性分别对微球的性能进行研究。结果:京尼平-壳聚糖微球表面光滑,平均粒径在5.1~50.5μm之间;京尼平的浓度可影响微球在体外释放神经生长因子的速度,经高浓度京尼平交联的微球能减缓并持续释放神经生长因子;此外,从京尼平-壳聚糖微球释放的神经生长因子可维持PC12细胞的生物活性,提高NGF生物利用率。结论:京尼平-壳聚糖微球能有效缓释具有生物活性的NGF超过14天,为神经退行性疾病的治疗提供一种治疗策略。     

装载于PLGA中的5-氟尿嘧啶缓释微球的制备及其体外释放的研究

目的:研究装载于不同分子量的PLGA中的5-氟尿嘧啶微球的制备方法及其在体外条件下的缓释行为。方法:以水包油包固复乳法将5-氟尿嘧啶包裹在高分子聚乳酸-聚羟基乙酸共聚物(PLGA)中,形成缓释微球,考察其大小,外观,包封率等理化性质,以紫外分光光度法为检测方法研究其体外释放行为。结果:经扫描电子显微镜观察,所制备的微球形态完整,大小较均匀。具有一定得包封率和载药量,体外释放研究表明其处方1和处方2的缓释时间为8天和23天。结论:以水包油包固复乳法制备的PLGA 5-氟尿嘧啶微球能够达到缓释的目的。     

干扰素α缓释微球的制备及体外释放研究

目的:开发一种有效地长效缓释干扰素α微球制剂。方法:利用S/O/W乳剂-挥发法制备了包裹干扰素α多糖颗粒的PLAG微球,对其外观形态进行了考察,并用ELISA方法考察了微球体外释放效果。结果:制备的干扰素α微球圆整光滑,粒径均匀;经24天体外释放,累计释放率达到80%以上。结论:通过包封包裹干扰素α的多糖颗粒进PLGA微球,有效地保护了干扰素α在微球中的活性,实现了长效缓释,是一种可行的缓释方案。     

rhEGF缓释微球对糖尿病皮肤溃疡创面修复的 作用

采用W/O/W方法制备聚乳酸-羟基乙酸共聚物(PLGA)载重组人表皮生长因子(rhEGF)缓释微球, 表征了缓释微球形貌和粒径分布, 研究了体外释放行为, 进行了细胞实验和动物实验. 结果显示：微球形貌规则, 粒径均匀; 药物包封率达85.6%; 缓释时间达24 h. 细胞实验表明, 微球比rhEGF原液具有更好的促进细胞增殖作用; 通过观察动物实验中溃疡面积变化、组织病理切片和PCNA表达, 发现微球组治疗效果优于生长因子原液组和空白对照组, 并且具有显著性差异. 本研究为rhEGF缓释微球技术的临床应用提供了重要的科学依据.     

纳米微球药物缓释技术

纳米微球作为药物载体被越来越多地应用于医药领域,这一技术得到研究者的广泛重视。目前已有多种纳米微球制剂投入临床使用。纳米微球的深入研究具有重要的意义。我们概述了近年来纳米微球的研究及应用情况,展望了纳米微球药物载体缓释技术的应用前景及需要解决的问题。     

左旋多巴甲酯缓释微球的研究

目的：由于长期服用左旋多巴治疗帕金森病,其药物浓度波动刺激易引起异动症,本实验旨在制备突释小,药物释放浓度稳定的左旋多巴甲酯微球制剂。方法：将左旋多巴甲酯用复乳法包裹于PLGA微球内,采用C18反相色谱研究药物包封率和体外释放行为。结果：通过调节药物浓度和不同高分子组合筛选出突释小,包封率高且缓慢释放的处方。结论：左旋多巴甲酯包裹于PLGA能实现理想的缓释效果,降低药物浓度波动,为后期药效学实验提供基础。     

Single-dose azithromycin microsphere formulation: a novel delivery system for antibiotics

Azithromycin extended release (Zmax, Pfizer Inc) is a novel single-dose administration formulation of azithromycin which won FDA approval in June 2005 and is currently approved for the treatment of community acquired pneumonia and acute bacterial sinusitis. Azitromycin is incorporated into sustained-release microspheres which release the drug slowly through 200 microm pores. Because of this sustained release mechanism, most of the drug is released into the lower gastrointestinal tract, reducing gastrointestinal side-effects, and allowing for a higher dose to be administered. The unique pharmacological properties and extremely long half-life of azithromycin make this drug well suited to single-dose administration but gastrointestinal side effects have previously hampered single-dose therapy.     

Developing a highly stable PLGA-mPEG nanoparticle loaded with cisplatin for chemotherapy of ovarian cancer

Background

Cisplatin is a potent anticancer drug, but its clinical application has been limited due to its undesirable physicochemical characteristics and severe side effects. Better drug formulations for cisplatin are highly desired.

Methodology/Principal Findings

Herein, we have developed a nanoparticle formulation for cisplatin with high encapsulation efficiency and reduced toxicity by using cisplatin-crosslinked carboxymethyl cellulose (CMC) core nanoparticles made from poly(lactide-co-glycolide)-monomethoxy-poly(polyethylene glycol) copolymers (PLGA-mPEG). The nanoparticles have an average diameter of approximately 80 nm measured by transmission electron microscope (TEM). The encapsulation efficiency of cisplatin in the nanoparticles is up to 72%. Meanwhile, we have also observed a controlled release of cisplatin in a sustained manner and dose-dependent treatment efficacy of cisplatin-loaded nanoparticles against IGROV1-CP cells. Moreover, the median lethal dose (LD₅₀) of the cisplatin-loaded nanoparticles was more than 100 mg/kg by intravenous administration, which was much higher than that of free cisplatin.

Conclusion

This developed cisplatin-loaded nanoparticle is a promising formulation for the delivery of cisplatin, which will be an effective therapeutic regimen of ovarian cancer without severe side effects and cumulative toxicity.     

Epidural Sustained Release Ropivacaine Prolongs Anti-Allodynia and Anti-Hyperalgesia in Developing and Established Neuropathic Pain

Ropivacaine is a local anesthetic widely used for regional anesthesia and epidural analgesia, but its relatively short duration limits its clinical use. A novel sustained release lipid formulation of ropivacaine has been recently developed to prolong its duration. We examined the epidural anti-hypersensitivity and preemptive effects of ropivacaine in mesylate injection and sustained release suspension forms in a rat model of neuropathy produced by peripheral nerve injury. Epidural administration of ropivacaine mesylate injection specifically blocked mechanical allodynia and thermal hyperalgesia by approximately 50% with a biological half-effective duration of approximately 3 hrs. The equivalent dose of ropivacaine free-base in sustained release suspension significantly prolonged the duration of anti-allodynia and anti-hyperalgesia by approximately 2 times. Multiple daily epidural injections of ropivacaine in both the mesylate injection and sustained-release suspension forms did not induce tolerance or potentiation to anti-allodynia or anti-hyperalgesia. Moreover, the single or multiple daily administration of ropivacaine mesylate injection before surgery in particular, markedly blocked the initiation and development of neuropathic pain, increasing the biological half-effective duration from less than 4 hrs up to 1 or 2 days. The single and multiple daily epidural injection of ropivacaine sustained release suspension further delayed the biological half-lives to 2 and 3 days, respectively. Our results indicate that the epidural administration of ropivacaine effectively blocks neuropathic pain without the induction of analgesic tolerance, and significantly delays the development of neuropathy produced by peripheral nerve injury. Epidural ropivacaine sustained release suspension produces much longer blockade effects of mechanical allodynia and heat hyperalgesia, and more significantly delays the development of neuropathic pain.     

Poly(lactic-co-glycolic acid) nanospheres and microspheres for short- and long-term delivery of bioactive ciliary neurotrophic factor

Ciliary neurotrophic factor (CNTF) has been shown to be neuroprotective in the central nervous system (CNS). However, systemic administration and bolus injections have shown significant side effects and limited efficacy. Sustained, local delivery may lead to effective neuroprotection and avoid or limit adverse side effects, but sustained CNTF delivery has proven difficult to achieve and control. For controlled, sustained delivery, we investigated several processing variables in making poly(DL-lactic-co-glycolic acid) (PLGA) nano- and microspheres to optimize CNTF encapsulation and release. Nano- and microspheres were 314.9 +/- 24.9 nm and 11.69 +/- 8.16 microm in diameter, respectively. CNTF delivery from nanospheres was sustained over 14 days, and delivery from microspheres continued over more than 70 days. To assess protein bioactivity after encapsulation, neural stem cells (NSCs) were treated with CNTF released from nanospheres and compared to those treated with unencapsulated CNTF as a control. NSCs treated with CNTF expressed markers specific to mature cells, notably astrocytes; some increase in oligodendrocytic and neuronal marker expression was also observed. Significantly, cells treated with CNTF released by nanospheres exhibited a similar degree of differentiation when compared to those treated with control CNTF of equivalent concentration, showing that the process of protein encapsulation did not reduce its potency.     

Sustained release of an anti-glaucoma drug: demonstration of efficacy of a liposomal formulation in the rabbit eye

Topical medication remains the first line treatment of glaucoma; however, sustained ocular drug delivery via topical administration is difficult to achieve. Most drugs have poor penetration due to the multiple physiological barriers of the eye and are rapidly cleared if applied topically. Currently, daily topical administration for lowering the intra-ocular pressure (IOP), has many limitations, such as poor patient compliance and ocular allergy from repeated drug administration. Poor compliance leads to suboptimal control of IOP and disease progression with eventual blindness. The delivery of drugs in a sustained manner could provide the patient with a more attractive alternative by providing optimal therapeutic dosing, with minimal local toxicity and inconvenience. To investigate this, we incorporated latanoprost into LUVs (large unilamellar vesicles) derived from the liposome of DPPC (di-palmitoyl-phosphatidyl-choline) by the film hydration technique. Relatively high amounts of drug could be incorporated into this vesicle, and the drug resides predominantly in the bilayer. Vesicle stability monitored by size measurement and DSC (differential scanning calorimetry) analysis showed that formulations with a drug/lipid mole ratio of about 10% have good physical stability during storage and release. This formulation demonstrated sustained release of latanoprost in vitro, and then tested for efficacy in 23 rabbits. Subconjunctival injection and topical eye drop administration of the latanoprost/liposomal formulation were compared with conventional daily administration of latanoprost eye drops. The IOP lowering effect with a single subconjunctival injection was shown to be sustained for up to 50 days, and the extent of IOP lowering was comparable to daily eye drop administration. Toxicity and localized inflammation were not observed in any treatment groups. We believe that this is the first demonstration, in vivo, of sustained delivery to the anterior segment of the eye that is safe and efficacious for 50 days.     

Comparison of bone morphogenetic protein-2 and osteoactivin for mesenchymal cell differentiation: effects of bolus and continuous administration

Current osteoinductive protein therapy utilizes bolus administration of large doses of bone morphogenetic proteins (BMPs), which is costly, and may not replicate normal bone healing. The limited in vivo biologic activity of BMPs requires the investigation of growth factors that may enhance this activity. In this study, we utilized the C3H10T1/2 murine mesenchymal stem cell line to test the hypotheses that osteoactivin (OA) has comparable osteoinductive effects to bone morphogenetic protein-2 (BMP-2), and that sustained administration of either growth factor would result in increased osteoblastic differentiation as compared to bolus administration. Sustained release biodegradable hydrogels were designed, and C3H10T1/2 cells were grown on hydrogels loaded with BMP-2 or OA. Controls were grown on unloaded hydrogels, and positive controls were exposed to bolus growth factor administration. Cells were harvested at several time points to assess osteoblastic differentiation. Alkaline phosphatase (ALP) staining and activity, and gene expression of ALP and osteocalcin were assessed. Treatment with OA or BMP-2 resulted in comparable effects on osteoblastic marker expression. However, cells grown on hydrogels demonstrated osteoblastic differentiation that was not as robust as cells treated with bolus administration. This study shows that OA has comparable effects to BMP-2 on osteoblastic differentiation using both bolus administration and continuous release, and that bolus administration of OA has a more profound effect than administration using hydrogels for sustained release. This study will lead to a better understanding of appropriate delivery methods of osteogenic growth factors like OA for repair of fractures and segmental bone defects.     

O6-methylguanine-DNA-methyltransferase (MGMT) gene therapy targeting haematopoietic stem cells: studies addressing safety issues

As haematopoietic stem cell gene therapy utilizing O(6)-methylguanine-DNA-methyltransferase has reached the clinical stage, safety-related questions become increasingly important. These issues concern insertional mutagenesis of viral vectors, the acute toxicity of pre-transplant conditioning protocols and in vivo selection regimens as well as potential genotoxic side effects of the alkylating drugs administered in this context. To address these questions, we have investigated toxicity-reduced conditioning regimens combining low-dose alkylator application with sublethal irradiation and have analysed their influence on engraftment and subsequent selectability of transduced haematopoietic stem cells. In addition, a strategy to monitor the acute and long-term genotoxic effects of drugs with high guanine-O(6) alkylating potential, such as chloroethylnitrosoureas or temozolomide is introduced. For this purpose, assays were implemented which allow an assessment of the generation and fate of primary drug-induced adducts as well as their long-term effect on chromosomal integrity at the single cell level.     

Calcium Binding-Mediated Sustained Release of Minocycline from Hydrophilic Multilayer Coatings Targeting Infection and Inflammation

Infection and inflammation are common complications that seriously affect the functionality and longevity of implanted medical implants. Systemic administration of antibiotics and anti-inflammatory drugs often cannot achieve sufficient local concentration to be effective, and elicits serious side effects. Local delivery of therapeutics from drug-eluting coatings presents a promising solution. However, hydrophobic and thick coatings are commonly used to ensure sufficient drug loading and sustained release, which may limit tissue integration and tissue device communications. A calcium-mediated drug delivery mechanism was developed and characterized in this study. This novel mechanism allows controlled, sustained release of minocycline, an effective antibiotic and anti-inflammatory drug, from nanoscale thin hydrophilic polyelectrolyte multilayers for over 35 days at physiologically relevant concentrations. pH-responsive minocycline release was observed as the chelation between minocycline and Ca²⁺ is less stable at acidic pH, enabling ‘smart’ drug delivery in response to infection and/or inflammation-induced tissue acidosis. The release kinetics of minocycline can be controlled by varying initial loading, Ca²⁺ concentration, and Ca²⁺ incorporation into different layers, enabling facile development of implant coatings with versatile release kinetics. This drug delivery platform can potentially be used for releasing any drug that has high Ca²⁺ binding affinity, enabling its use in a variety of biomedical applications.     

Peptide hydrogels for affinity-controlled release of therapeutic cargo: Current and potential strategies

The development of devices for the precise and controlled delivery of therapeutics has grown rapidly over the last few decades. Drug delivery materials must provide a depot with delivery profiles that satisfy pharmacodynamic and pharmacokinetic requirements resulting in clinical benefit. Therapeutic efficacy can be limited due to short half-life and poor stability. Thus, to compensate for this, frequent administration and high doses are often required to achieve therapeutic effect, which in turn increases potential side effects and systemic toxicity. This can potentially be mitigated by using materials that can deliver drugs at controlled rates, and material design principles that allow this are continuously evolving. Affinity-based release strategies incorporate a myriad of reversible interactions into a gel network, which have affinities for the therapeutic of interest. Reversible binding to the gel network impacts the release profile of the drug. Such affinity-based interactions can be modulated to control the release profile to meet pharmacokinetic benchmarks. Much work has been done developing affinity-based control in the context of polymer-based materials. However, this strategy has not been widely implemented in peptide-based hydrogels. Herein, we present recent advances in the use of affinity-controlled peptide gel release systems and their associated mechanisms for applications in drug delivery.