Solid Lipid Nanoparticles as Delivery Systems for Bioactive Food Components

The inclusion of bioactive compounds, such as carotenoids, omega-3 fatty acids, or phytosterols, is an essential requisite for the production of functional foods designed to improve the long-term health and well-being of consumers worldwide. To incorporate these functional components successfully in a food system, structurally sophisticated encapsulation matrices have to be engineered, which provide maximal physical stability, protect ingredients against chemical degradation, and allow for precise control over the release of encapsulated components during mastication and digestion to maximize adsorption. A novel encapsulation system initially developed in the pharmaceutical industries to deliver lipophilic bioactive compounds is solid lipid nanoparticles (SLN). SLN consist of crystallized nanoemulsions with the dispersed phase being composed of a solid carrier lipid–bioactive ingredient mixture. Contrary to larger colloidal solid lipid particles, specific crystal structures can be “dialed-in” in SLN by using specific surfactant mixtures and ensuring that mean particle sizes are below 100–200 nm. Moreover, in SLN, microphase separations of the bioactive compound from the solidifying lipid matrix can be prevented resulting in an even dispersion of the encapsulated compound in the solid matrix thereby improving chemical and physical stability of the bioactive. In this review article, we will briefly introduce the structure, properties, stability, and manufacturing of solid lipid particles and discuss their emerging use in food science.     

Preparation and Evaluation of Miconazole Nitrate-Loaded Solid Lipid Nanoparticles for Topical Delivery

The purpose of this study was to prepare miconazole nitrate (MN) loaded solid lipid nanoparticles (MN-SLN) effective for topical delivery of miconazole nitrate. Compritol 888 ATO as lipid, propylene glycol (PG) to increase drug solubility in lipid, tween 80, and glyceryl monostearate were used as the surfactants to stabilize SLN dispersion in the SLN preparation using hot homogenization method. SLN dispersions exhibited average size between 244 and 766 nm. All the dispersions had high entrapment efficiency ranging from 80% to 100%. The MN-SLN dispersion which showed good stability for a period of 1 month was selected. This MN-SLN was characterized for particle size, entrapment efficiency, and X-ray diffraction. The penetration of miconazole nitrate from the gel formulated using selected MN-SLN dispersion as into cadaver skins was evaluated ex-vivo using franz diffusion cell. The results of differential scanning calorimetry (DSC) showed that MN was dispersed in SLN in an amorphous state. The MN-SLN formulations could significantly increase the accumulative uptake of MN in skin over the marketed gel and showed a significantly enhanced skin targeting effect. These results indicate that the studied MN-SLN formulation with skin targeting may be a promising carrier for topical delivery of miconazole nitrate.     

Preparation and Enhanced Oral Bioavailability of Cryptotanshinone-Loaded Solid Lipid Nanoparticles

In this study, solid lipid nanoparticles (SLNs) were successfully prepared by an ultrasonic and high-pressure homogenization method to improve the oral bioavailability of the poorly water-soluble drug cryptotanshinone (CTS). The particle size and distribution, drug loading capacity, drug entrapment efficiency, zeta potential, and long-term physical stability of the SLNs were characterized in detail. A pharmacokinetic study was conducted in rats after oral administration of CTS in different SLNs, and it was found that the relative bioavailability of CTS in the SLNs was significantly increased compared with that of a CTS-suspension. The incorporation of CTS in SLNs also markedly changes the metabolism behavior of CTS to tanshinone IIA. These results indicate that CTS absorption is enhanced significantly by employing SLN formulations, and SLNs represent a powerful approach for improving the oral absorption of poorly soluble drugs.     

Development,Optimization, and Evaluation of Carvedilol-Loaded Solid Lipid Nanoparticles for Intranasal Drug Delivery

Carvedilol, a beta-adrenergic blocker, suffers from poor systemic availability (25%) due to first-pass metabolism. The aim of this work was to improve carvedilol bioavailability through developing carvedilol-loaded solid lipid nanoparticles (SLNs) for nasal administration. SLNs were prepared by emulsion/solvent evaporation method. A 2³ factorial design was employed with lipid type (Compritol or Precirol), surfactant (1 or 2% w/v poloxamer 188), and co-surfactant (0.25 or 0.5% w/v lecithin) concentrations as independent variables, while entrapment efficiency (EE%), particle size, and amount of carvedilol permeated/unit area in 24 h (Q ₂₄) were the dependent variables. Regression analysis was performed to identify the optimum formulation conditions. The in vivo behavior was evaluated in rabbits comparing the bioavailability of carvedilol after intravenous, nasal, and oral administration. The results revealed high drug EE% ranging from 68 to 87.62%. Carvedilol-loaded SLNs showed a spherical shape with an enriched core drug loading pattern having a particle size in the range of 66 to 352 nm. The developed SLNs exhibited significant high amounts of carvedilol permeated through the nasal mucosa as confirmed by confocal laser scanning microscopy. The in vivo pharmacokinetic study revealed that the absolute bioavailability of the optimized intranasal SLNs (50.63%) was significantly higher than oral carvedilol formulation (24.11%). Hence, we conclude that our developed SLNs represent a promising carrier for the nasal delivery of carvedilol.     

Diazepam-Loaded Solid Lipid Nanoparticles: Design and Characterization

The aim of the present study was to investigate the feasibility of the inclusion of a water-insoluble drug (diazepam, DZ) into solid lipid nanoparticles (SLNs), which offer combined advantages of rapid onset and prolonged release of the drug. This work also describes a new approach to prepare suppositories containing DZ-loaded SLN dispersions, as potential drug carrier for the rectal route. Modified high-shear homogenization and ultrasound techniques were employed to prepare SLNs. The effect of incorporation of different concentrations of Compritol® ATO 888 or Imwitor® 900K and Poloxamer 188 or Tween 80 was investigated. Results showed that varying the type or concentration of lipid matrix or surfactant had a noticeable influence on the entrapment efficiencies, particle size, and release profiles of prepared SLNs. Differential scanning calorimetry and X-ray diffraction measurements showed that the majority of SLNs possessed less ordered arrangements of crystals than the corresponding bulk lipids, which was favorable for increasing the drug loading capacity. Transmission electron microscopy and laser diffractometry studies revealed that the prepared nanoparticles were round and homogeneous and 60% of the formulations were less than 500 nm. Additionally, SLN formulations showed significant (P?in vitro release of DZ from the suppositories prepared using DZ-loaded SLN dispersions (equivalent to 2 mg DZ) was significantly (P?相似文献   

Physical-Chemical Characterization and Formulation Considerations for Solid Lipid Nanoparticles

Pure glyceryl mono-oleate (GMO) (lipid) and different batches of GMO commonly used for the preparation of GMO-chitosan nanoparticles were characterized by modulated differential scanning calorimetry (MDSC), cryo-microscopy, and cryo-X-ray powder diffraction techniques. GMO-chitosan nanoparticles containing poloxamer 407 as a stabilizer in the absence and presence of polymers as crystallization inhibitors were prepared by ultrasonication. The effect of polymers (polyvinyl pyrrolidone (PVP), Eudragits, hydroxyl propyl methyl cellulose (HPMC), polyethylene glycol (PEG)), surfactants (poloxamer), and oils (mineral oil and olive oil) on the crystallization of GMO was investigated. GMO showed an exothermic peak at around ?10°C while cooling and another exothermic peak at around ?12°C while heating. It was followed by two endothermic peaks between 15 and 30 C, indicative of GMO melting. The results are corroborated by cryo-microscopy and cryo-X-ray. Significant differences in exothermic and endothermic transition were observed between different grades of GMO and pure GMO. GMO-chitosan nanoparticles resulted in a significant increase in particle size after lyophilization. MDSC confirmed that nanoparticles showed similar exothermic crystallization behavior of lipid GMO. MDSC experiments showed that PVP inhibits GMO crystallization and addition of PVP showed no significant increase in particle size of solid lipid nanoparticle (SLN) during lyophilization. The research highlights the importance of extensive physical-chemical characterization for successful formulation of SLN.     

Transfersomal Nanoparticles for Enhanced Transdermal Delivery of Clindamycin

The aim of this work was to study the potential of delivering clindamycin phosphate, as an efficient antibiotic drug, into a more absorbed, elastic ultradeformable form, transfersomes (TRSs). These vesicles showed an enhanced penetration through ex vivo permeation characters. TRSs were prepared using thin-film hydration method. Furthermore, they were evaluated for their entrapment efficiency, size, zeta potential, and morphology. Also, the prepared TRSs were converted into suitable gel formulation using carbopol 934 and were evaluated for their gel characteristics like pH, viscosity, spreadability, homogeneity, skin irritation, in vitro release, stability, and ex vivo permeation studies in rats. TRSs were efficiently formulated in a stable bilayer vesicle structure. Furthermore, clindamycin phosphate showed higher entrapment efficiency within the TRSs reaching about 93.3%?±?0.8 and has a uniform particle size. Moreover, the TRSs surface had a high negative charge which indicated the stability of the produced vesicles and resistance of aggregation. Clindamycin phosphate showed a significantly higher in vitro release (p?<?0.05; ANOVA/Tukey) compared with the control carbopol gel. Furthermore, the transfersomal gel showed a significantly higher (p?<?0.05; ANOVA/Tukey) cumulative amount of drug permeation and flux than both the transfersomal suspension and the control carbopol gel. In conclusion, the produced results suggest that TRS-loaded clindamycin are promising carriers for enhanced dermal delivery of clindamycin phosphate.     

综述——纳米材料与药物输递：脂质纳米粒在口服给药系统中的应用

脂质纳米粒是由固体脂肪酸或其酯类制成的一类纳米制剂,其生物相容性好、安全性好,所以在药物递送领域受到广泛关注．难溶性药物、多肽及蛋白质药物由于溶解度、跨膜能力以及稳定性等问题,导致口服生物利用度低,而利用脂质纳米粒作为其载体,口服给药后能显著改善药物的生物利用度,这使得脂质纳米粒在口服给药系统中得到了广泛的应用与研究．本文从口服脂质纳米粒的处方、制备工艺、吸收机制以及应用四个方面对其进行了详细的综述．     

综述——纳米材料与药物输递：基于聚合物的环境敏感型纳米抗肿瘤药物传输系统的研究

环境敏感型聚合物纳米抗肿瘤药物传递系统能够响应外界环境的微小刺激,引起自身结构的变化,释放出药物,在肿瘤治疗方面具长效低毒、可控及高载药量等优势,已被广泛应用于生物医学领域．本文介绍了聚合物环境响应型纳米药物传输系统的发展近况,并从pH 值敏感型、温度敏感型、氧化还原敏感型、酶敏感型以及其他敏感型给药系统角度,阐述了环境敏感型药物传输系统在抗肿瘤领域的研究现状及未来展望．     

Design and Characterization of Metformin-Loaded Solid Lipid Nanoparticles for Colon Cancer

Colorectal cancer is a global concern, and its treatment is fraught with non-selective effects including adverse side effects requiring hospital visits and palliative care. A relatively safe drug formulated in a bioavailability enhancing and targeting delivery platform will be of significance. Metformin-loaded solid lipid nanoparticles (SLN) were designed, optimized, and characterized for particle size, zeta potential, drug entrapment, structure, crystallinity, thermal behavior, morphology, and drug release. Optimized SLN were 195.01?±?6.03 nm in size, ?17.08?±?0.95 mV with regard to surface charge, fibrous in shape, largely amorphous, and release of metformin was controlled. The optimized size, charge, and shape suggest the solid lipid nanoparticles will migrate and accumulate in the colon tumor preventing its proliferation and subsequently leading to tumor shrinkage and cell death.     

Solid Lipid Nanoparticles (SLNs) for Intracellular Targeting Applications

Nanoparticle-based delivery vehicles have shown great promise for intracellular targeting applications, providing a mechanism to specifically alter cellular signaling and gene expression. In a previous investigation, the synthesis of ultra-small solid lipid nanoparticles (SLNs) for topical drug delivery and biomarker detection applications was demonstrated. SLNs are a well-studied example of a nanoparticle delivery system that has emerged as a promising drug delivery vehicle. In this study, SLNs were loaded with a fluorescent dye and used as a model to investigate particle-cell interactions. The phase inversion temperature (PIT) method was used for the synthesis of ultra-small populations of biocompatible nanoparticles. A 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenylphenyltetrazolium bromide (MTT) assay was utilized in order to establish appropriate dosing levels prior to the nanoparticle-cell interaction studies. Furthermore, primary human dermal fibroblasts and mouse dendritic cells were exposed to dye-loaded SLN over time and the interactions with respect to toxicity and particle uptake were characterized using fluorescence microscopy and flow cytometry. This study demonstrated that ultra-small SLNs, as a nanoparticle delivery system, are suitable for intracellular targeting of different cell types.     

多西他赛固体脂质纳米粒抗乳腺癌效果及机制研究

目的:探讨多西他赛固体脂质纳米粒抗乳腺癌效果及机制研究。方法:本实验采用MTT法考察了多西他赛固体脂质纳米粒对人乳腺癌MCF-7细胞增殖的抑制作用,采用流式细胞术检测多西他赛固体脂质纳米粒对MCF-7肿瘤细胞凋亡作用,并进一步应用Western-Blot印迹法观察多西他赛固体脂质纳米粒对MCF-7细胞中Src、E-cadherin、β-catenin蛋白表达的影响,探索了其抗乳腺肿瘤的作用机制。结果:多西他赛固体脂质纳米粒能够显著抑制人乳腺癌MCF-7肿瘤细胞的增殖,且浓度越高,抑制率越大(P0.05)。经25、50、100μg/m L多西他赛固体脂质纳米粒制剂作用24 h后,人乳腺癌细胞MCF-7的凋亡率分别为14.56%、21.21%、29.94%,细胞凋亡率随着药物浓度的增加而增加,且各实验组间比较有显著性差异(P0.05)。人乳腺癌MCF-7肿瘤细胞经不同浓度的多西他赛固体脂质纳米粒处理后,细胞中E-cadherin蛋白表达显著升高,Src、β-catenin蛋白表达显著降低,且呈现出明显的剂量依赖性。结论:多西他赛固体脂质纳米粒能够抑制人乳腺癌MCF-7细胞增殖,促进其凋亡,可能与下调β-catenin蛋白的表达,上调E-cadherin蛋白表达以及抑制Src激酶活性有关。     

壳聚糖和帕米膦酸双修饰的固体脂质纳米粒的制备

目的:制备壳聚糖和帕米膦酸双修饰的固体脂质纳米粒。方法:首先利用课题组发表的专利合成帕米膦酸修饰Brij78的新型非离子表面活性剂(Pa-Brij78),然后以壳聚糖(CS)溶液为水相,Pa-Brij78为乳化剂,E-Wax为油相,采用微乳法,利用修饰的帕米膦酸基团与壳聚糖分子链中质子化的氨基交联反应原理,通过一系列实验条件的探索,确定了最佳实验工艺条件,成功制备了壳聚糖和帕米膦酸双修饰的固体脂质纳米粒。通过动态光散射(DLS)粒径仪测定了纳米粒的粒径大小和Zeta电位;透射电子显微镜(TEM)对CS-Pa-Brij78-SLNs的形貌结构进行了表征。结果:实验结果显示,制备壳聚糖和帕米膦酸双修饰的固体脂质纳米粒的最佳条件为:p H=6.0,壳聚糖浓度分别为0.1%,0.2%;反应温度65℃,反应时间40 min,在该条件下,制备的壳聚糖和帕米膦酸双修饰的固体脂质纳米粒(CS-Pa-Brij78-SLNs)粒径分别为97.9±6.6 nm和182.4±62.2 nm,表面电位分别为(+5.21±1.4m V);(+7.94±0.80 m V),装载姜黄素时,载药量为10%,包封率在90%以上,透射电镜下观察其形态圆整,清晰可见壳聚糖包裹的电晕。结论:本文以壳聚糖(CS)溶液为水相,合成的新型非离子表面活性剂Pa-Brij78为乳化剂,E-Wax为油相,采用微乳化法,经过最佳实验条件的探索,通过一步法成功制备了稳定的壳聚糖和帕米膦酸双修饰的固体脂质纳米粒(CS-Pa-Brij78-SLNs)。     

Orally Administered Therapeutic Peptide Delivery: Enhanced Absorption Through the Small Intestine Using Permeation Enhancers

Peptide therapeutics (PTs) is generally regarded as highly effective macromolecule therapeutics at very low concentrations. The main issues surrounding the administration of PTs is guaranteeing that they are bioavailable, reach the desired therapeutic index and distribute throughout the body effectively. The oral administration, a non-invasive route, of PTs is considered a major complication due to inadequate oral absorption through biological membranes such as the small intestine epithelium due to presystemic proteolytic enzymatic activity. PTs bioavailability is further diminished in the systemic circulation due to low stability in the plasma and rapid excretion from the body. Many alternative routes can be considered non-invasive such as transdermal and nasal routes, but this review focuses on the oral route, specifically the small intestine region of the gastrointestinal tract. Although this region has the highest density of proteolytic enzymes, it contains tight junctions which have the lowest trans-epithelial electrical resistance throughout the body; thus paracellular transport of these large PTs can be achieved more readily. The use of a natural polysaccharide polymer, such as trimethyl chitosan (TMC), which enhances the bioavailability of these PTs through the small intestine, will also be discussed in great detail. TMC has been considered because it could potentially solve many of the mechanistic and chemical problems associated with oral therapeutic peptide administration. The safety of orally administered PTs through the small intestinal epithelium employing a polymer such as TMC is also discussed as this is a significant issue for regulatory bodies.     

Chitosan-Nanoconjugated Hormone Nanoparticles for Sustained Surge of Gonadotropins and Enhanced Reproductive Output in Female Fish

A controlled release delivery system helps to overcome the problem of short life of the leutinizing hormone releasing hormone (LHRH) in blood and avoids use of multiple injections to enhance reproductive efficacy. Chitosan- and chitosan-gold nanoconjugates of salmon LHRH of desired size, dispersity and zeta potential were synthesized and evaluated at half the dose rate against full dose of bare LHRH for their reproductive efficacy in the female fish, Cyprinus carpio. Whereas injections of both the nanoconjugates induced controlled and sustained surge of the hormones with peak (P<0.01) at 24 hrs, surge due to bare LHRH reached its peak at 7 hrs and either remained at plateau or sharply declined thereafter. While the percentage of relative total eggs produced by fish were 130 and 67 per cent higher, that of fertilised eggs were 171 and 88 per cent higher on chitosan- and chitosan-gold nanoconjugates than bare LHRH. Chitosan nanoconjugates had a 13 per cent higher and chitosan gold preparation had a 9 per cent higher fertilization rate than bare LHRH. Histology of the ovaries also attested the pronounced effect of nanoparticles on reproductive output. This is the first report on use of chitosan-conjugated nanodelivery of gonadotropic hormone in fish.     

Polymeric Micelles: Nanocarriers for Cancer-Targeted Drug Delivery

Polymeric micelles represent an effective delivery system for poorly water-soluble anticancer drugs. With small size (10–100 nm) and hydrophilic shell of PEG, polymeric micelles exhibit prolonged circulation time in the blood and enhanced tumor accumulation. In this review, the importance of rational design was highlighted by summarizing the recent progress on the development of micellar formulations. Emphasis is placed on the new strategies to enhance the drug/carrier interaction for improved drug-loading capacity. In addition, the micelle-forming drug-polymer conjugates are also discussed which have both drug-loading function and antitumor activity.     

固体脂质纳米粒的制备及在治疗中的应用研究

固体脂质纳米粒(SLN)是20世纪90年代发展起来的一种性能优异的新型纳米粒给药剂型作为一种新型载体,可有效提高包封药物的稳定性、提高病变部位靶向性、低毒性与组织亲和性,为药物的体内递送提供了一种新的方法。本文主要针对固体脂质纳米粒的制备,发展现状,目前存在的问题及解决思路等作以介绍与总结。并在此基础上,介绍了新的脂质纳米粒,纳米脂质载体(nanostructured lipid carriers,NLC)和药脂结合物纳米粒(Lipid drug conjugate nanoparticles,LDC),以及未来固体脂质纳米粒的发展方向。     

Recent Advances in Lipid Nanoparticle Formulations with Solid Matrix for Oral Drug Delivery

Lipid nanoparticles based on solid matrix have emerged as potential drug carriers to improve gastrointestinal (GI) absorption and oral bioavailability of several drugs, especially lipophilic compounds. These formulations may also be used for sustained drug release. Solid lipid nanoparticle (SLN) and the newer generation lipid nanoparticle, nanostructured lipid carrier (NLC), have been studied for their capability as oral drug carriers. Biodegradable, biocompatible, and physiological lipids are generally used to prepare these nanoparticles. Hence, toxicity problems related with the polymeric nanoparticles can be minimized. Furthermore, stability of the formulations might increase than other liquid nano-carriers due to the solid matrix of these lipid nanoparticles. These nanoparticles can be produced by different formulation techniques. Scaling up of the production process from lab scale to industrial scale can be easily achieved. Reasonably high drug encapsulation efficiency of the nanoparticles was documented. Oral absorption and bioavailability of several drugs were improved after oral administration of the drug-loaded SLNs or NLCs. In this review, pros and cons, different formulation and characterization techniques, drug incorporation models, GI absorption and oral bioavailability enhancement mechanisms, stability and storage condition of the formulations, and recent advances in oral delivery of the lipid nanoparticles based on solid matrix will be discussed.     

抗生素缓控释给药系统——载药微球的研究与开发

利用具良好生物相容性和生物可降解性的聚合物制得的微球作为一种新型药物载体, 具有良好的缓控释作用,并具有一定的靶向性,可用于口服和注射,在药学领域和临床上有着广阔的应用前景。综述近年来各种抗生素缓控释微球制剂的研究与开发。     

Darunavir-Loaded Lipid Nanoparticles for Targeting to HIV Reservoirs

Darunavir has a low oral bioavailability (37%) due to its lipophilic nature, metabolism by cytochrome P450 enzymes and P-gp efflux. Lipid nanoparticles were prepared in order to overcome its low bioavailability and to increase the binding efficacy of delivery system to the lymphoid system. Darunavir-loaded lipid nanoparticles were prepared using high-pressure homogenization technique. Hydrogenated castor oil was used as lipid. Peptide, having affinity for CD4 receptors, was grafted onto the surface of nanoparticles. The nanoparticles were evaluated for various parameters. The nanoparticles showed size of less than 200 nm, zeta potential of ? 35.45 mV, and a high drug entrapment efficiency (90%). 73.12% peptide was found conjugated to nanoparticles as studied using standard BSA calibration plot. Permeability of nanoparticles in Caco-2 cells was increased by 4-fold in comparison to plain drug suspension. Confocal microscopic study revealed that the nanoparticles showed higher uptake in HIV host cells (Molt-4 cells were taken as model containing CD4 receptors) as compared to non-CD4 receptor bearing Caco-2 cells. In vivo pharmacokinetic in rats showed 569% relative increase in bioavailability of darunavir as compared to plain drug suspension. The biodistribution study revealed that peptide-grafted nanoparticles showed higher uptake in various organs (also in HIV reservoir organs namely the spleen and brain) except the liver compared to non-peptide-grafted nanoparticles. The prepared nanoparticles resulted in increased binding with the HIV host cells and thus could be promising carrier in active targeting of the drugs to the HIV reservoir.