The Application of Natural Carotenoids in Multiple Fields and Their Encapsulation Technology: A Review.

Carotenoids, which are inherent pigments occurring in plants and microorganisms, manifest a diverse array of vivid hues. Owing to their multifarious health advantages, carotenoids have engendered substantial interest among scholars and consumers alike. Presently, carotenoids are extensively employed in the realms of food, nutrition and health commodities, pharmaceuticals, and cosmetics, rendering them an indispensable constituent of our quotidian existence. Therefore, the objective of this review is to present a succinct and methodical examination of the sources, constituents, and factors influencing formation of carotenoids. Particular attention will be given to encapsulation strategies that maintain intrinsic characteristics, as the growing desire for carotenoids is propelled by individuals' escalating standards of living. Moreover, the applications of natural carotenoids in multiple fields, including pharmaceutical, food and feed, as well as cosmetics, are discussed in detail. Finally, this article explores the main challenges hindering the future advancement of carotenoids, aiming at facilitating their effective integration into the circular economy.

Impact of hypromellose acetate succinate and Soluplus® on the performance of ß-carotene solid dispersions with the aid of sorbitan monolaurate: In vitro-in vivo comparative assessment.

Solid dispersions (SDs) possess the potential to enhance the bioavailability of insoluble active pharmaceutical ingredients (APIs) by effectively converting them into amorphous state. However, SDs have a tendency to recrystallize unless appropriate excipients are employed. The objective of this study was to evaluate the ability of hypromellose acetate succinate HF (HPMCAS-HF) and Soluplus® to inhibit the recrystallization of ß-carotene and improve its in vivo bioavailability through the fabrication of ternary ß-carotene solid dispersions (SDs) with the aid of specific surfactant. Due to rapid micellization, the dissolution profiles of ß-carotene SDs based on HPMCAS-HF/Span 20 (5:5, w/w) or Soluplus®/Span 20 (6:4, w/w) combinations exhibited significant improvement, which were almost 7-10 times higher than ß-carotene bulk powder. DSC and PXRD analysis indicated a notable reduction in the crystallinity degree of ß-carotene within the SDs. The stability study demonstrated a half-life of ß-carotene in the SDs exceeding 30 days. Additionally, the in vivo pharmacokinetics analysis confirmed that the cellulose derivatives/surfactant combinations significantly enhanced the bioavailability of ß-carotene by 1.37-fold and 2.3-fold, respectively. Notably, the HPMCAS-HF/Span 20 combination exhibited superior performance. Consequently, the HPMCAS-HF/Span 20 combination held potential for the advancement of an effective drug delivery system for ß-carotene.

Comparative study of cyclosporine A liposomes and emulsions for ophthalmic drug delivery: Process optimization through response surface methodology (RSM) and biocompatibility evaluation.

Herein, cyclosporine A loaded liposomes (CsA-Lips) were fabricated aimed at improving the biocompatibility of the ophthalmic formulation and getting rid of the direct contact of ocular tissues with irritant excipients. Response surface methodology was exploited in order to investigate the influence of miscellaneous factors on the key characteristics of CsA-Lips. Ratio of EPC:CsA, ratio of EPC:Chol, and stirring speed were selected as the independent variables, while size, drug-loading content (DL), and drug-loading content (DL) loss rate were applied as the response variables. In case of the maximal lack-of-fit p-value and minimum sequential p-value, quadratic model was regarded as the fittest model to analyze the data. The correlation of independent variables with response variables was described by three-dimension surface figures. Optimized formulation for CsA-Lips was obtained with ratio of EPC:CsA set as 15, ratio of EPC:Chol set as 2, and stirring speed set as 800 rpm. The particle size of CsA-Lips was 129.2 nm after optimalization while their TEM images exhibited spherical unilamellar vesicles with clearly shell-core structure. CsA released more rapidly from CsA-Lips in comparison with self-made emulsion and Restasis®. Besides, minimum cytotoxicity of CsA-Lips was perceived via both MTT method and LDH method, indicating the excellent compatibility of the ophthalmic formulation. Simultaneously, CsA-Lips showed enhanced nonspecific internalization in the cytoplasm with a time-dose-dependent manner. In conclusion, CsA-Lips could be adhibited as the hopeful ophthalmic drug delivery system clinically for dry eye syndrome (DES).

Laser-responsive multi-functional nanoparticles for efficient combinational chemo-photodynamic therapy against breast cancer.

Herein, novel laser-responsive multi-functional nanoparticles (NPs-Lip@PTX/CyA/Ce6) were fabricated with bovine serum albumins (BSA) based nanoparticles, which simultaneously carried chemotherapeutic drug paclitaxel (PTX) and P-gp inhibitor cyclosporin A (CyA), as core and photosensitizer agent Chlorin e6 (Ce6) loaded Tf-modified liposomal bilayer as shell. NPs-Lip@PTX/CyA/Ce6 exhibited apparent core-shell structure morphology with particle size of 160.9 ± 1.7 nm and zeta potential of - 26.7 ± 0.6 mV, indicating their excellent stability in aqueous solution. Besides, NPs-Lip@PTX/CyA/Ce6 possessed laser-responsive release profiles upon laser irradiation at specific wavelength, which was favor to exert efficient combinatorial chemo-photodynamic therapy and effectively reverse the multiple drug resistance (MDR). Under laser irradiation, as expected, NPs-Lip@PTX/CyA/Ce6 demonstrated superb intracellular ROS productivity and fantastic in vitro and in vivo anti-cancer therapy effect but absent of systemic toxicity. In conclusion, the nano-drug delivery system would be prospectively applied in clinic as resultful therapeutic tactic for investing compositional chemo-photodynamic therapy synergistically.

Amorphous solid dispersions of cyclosporine A with improved bioavailability prepared via hot melt extrusion: Formulation, physicochemical characterization, and in vivo evaluation.

In this study, the amorphous solid dispersions of cyclosporine A (CsA-ASDs) were prepared by hot melt extrusion (HME) with PVP K12 as carrier to improve the oral bioavailability of CsA. The polymers were screened by solubilization and recrystallization inhibition experiments, then the CsA-ASDs were prepared with optimized technological parameters and characterized on thermodynamics and morphology. The results showed that CsA was dispersed among PVP K12 as amorphous form in CsA-ASDs, and the infrared spectrum testified that there was possible hydrogen bond interaction between CsA and PVP K12. The in vivo pharmacokinetics of CsA formulations in rats were analyzed via LC-MS. The AUC of CsA-ASD tablets increased by 7.3 times compared to CsA bulk powder and 3.1 times in contrast to CsA-PM tablets, respectively. The experiment proved that CsA-ASD tablets significantly improved the dissolution and absorption of the drug. This study had a reference value for the bioavailability improvement of oral CsA preparations.

Cellulose derivatives as effective recrystallization inhibitor for ternary ritonavir solid dispersions: In vitro-in vivo evaluation.

Amorphous solid dispersions (ASDs) are regarded as one of the most promising techniques for poorly-soluble active pharmaceutical ingredients (API). However, the thermodynamic instability of ASDs at supersaturated state makes them easy to recrystallize in aqueous media. In this study, ritonavir (RTV) was selected as a model drug for evaluating the solubility enhancement and recrystallization inhibition effect of various cellulose derivatives and the combinations of them with typical surfactants. Combination of HPMCAS-HF/SLS was filtrated for preparing ternary RTV solid dispersions (RTV SD) via solvent evaporation method. RTV SD exhibited enhanced dissolution manner, while the oral bioavailability of RTV SD was equivalent with the Reference Standard Norvir® but increased significantly compared to the ternary physical mixture. Thus, the ternary SD system might be promisingly employed as efficient drug delivery system for RTV, while the HPMCAS-HF/SLS combination could be recommended as effective excipient for fabricating steady solid dispersions loading poorly soluble API.

Amphiphilic block polymer-based self-assembly of high payload nanoparticles for efficient combinatorial chemo-photodynamic therapy.

Combinatorial chemo-photodynamic therapy is regared as effective cancer therapy strategy, which could be realized via multiple nano-drug delivery system. Herein, novel high payload nanoparticles stabilized by amphiphilic block polymer cholesterol-b-poly(ethylene glycol) (PEG)2000 (Chol-PEG2000) were fabricated for loading chemotherapeutic drug 10-hydroxycamptothecin (HCPT) and photosensitizer chlorin e6 (Ce6). The obtained HCPT/Ce6 NPs showed uniform rod-like morphology with a hydration diameter of 178.9 ± 4.0 nm and excellent stability in aqueous solution. HCPT and Ce6 in the NPs displayed differential release profile, which was benefit for preferentially exerting the photodynamic effect and subsequently enhancing the sensitivity of the cells to HCPT. Under laser irradiation, the NPs demonstrated fantastic in vitro and in vivo anticancer efficiency due to combinational chemo-photodynamic therapy, enhanced cellular uptake effectiveness, and superb intracellular ROS productivity. Besides, the NPs were proved as absent of systemic toxicity. In summary, this nanoparticle delivery system could be hopefully utilized as effective cancer therapy strategy for synergistically exerting combined chemo-photodynamic therapy in clinic.

Drug-binding albumins forming stabilized nanoparticles for co-delivery of paclitaxel and resveratrol: In vitro/in vivo evaluation and binding properties investigation.

Albumin has been regarded as the ideal drug carrier for delivering hydrophobic agents into cancer cells over decades. Combination therapy of paclitaxel (PTX) with resveratrol (RES) could enhance the sensitivity of multidrug resistance (MDR) cancer cell lines to PTX. In this study, novel paclitaxel/resveratrol co-loaded albumin nanoparticles (PTX/RES NPs) were developed to achieve synergistic anticancer efficacy and conquer paclitaxel resistance. The hybrid NPs had an average diameter of about 150 nm and an apparent negative surface charge of about -33 mV. PTX/RES NPs could be efficiently internalized by cells and exert synergistic combination efficacy of the two drugs, thus resulting in dramatically in vitro cytotoxicity even against MDR cancer cells. In vivo antitumor assay demonstrated that the antitumor effect of the hybrid NPs was superior to that of single drug-loaded NPs or free drug combination. Molecular docking analysis disclosed that the binding of PTX and RES to bovine serum albumin (BSA) was noncompetitive but the binding free energy of BSA/PTX dockings was significantly lower than BSA/RES dockings, which resulted in high encapsulation efficiency and sustained drug release profiles of PTX. In summary, the PTX/RES co-delivery system might be a promising strategy for combined anticancer therapy to overcome tumor drug resistance.

Novel carrier-free nanoparticles composed of 7-ethyl-10-hydroxycamptothecin and chlorin e6: Self-assembly mechanism investigation and in vitro/in vivo evaluation.

The combination therapy strategy based on both chemotherapy and photodynamic therapy (PDT) exhibits great potential for advanced cancer treatment. Multimodal nanodrug delivery systems based on both chemotherapeutic drug and photodynamic agent have been proven to possess excellent synergistic efficacy. In this study, 7-ethyl-10-hydroxycamptothecin (SN38) and chlorin e6 (Ce6) were co-assembled into novel carrier-free nanoparticles (SN38/Ce6 NPs) via simple antisolvent precipitation method. As expected, SN38/Ce6 NPs exhibited uniform morphology with a particle size of around 150 nm and a zeta potential of about -30 mV, good stability in aqueous solution/at lyophilized state and high cellular uptake efficiency against murine mammary carcinoma (4T1) cell lines. Besides, enhanced singlet oxygen generation capacity of the nanoparticles was both observed in test-tube and in 4T1 cell lines in contrast with Ce6 injection. Moreover, a ∼85 % inhibition rate of SN38/Ce6 NPs with laser was detected, which was significantly higher (P < 0.05) than those without laser (∼65 %) and injections (less than 20 %), verified the excellent synergistic antitumor efficacy of the nanoparticles due to combined chemo-photodynamic therapy, enhanced tumor accumulation and higher cellular internalization. Notably, chemical thermodynamic method and molecular dynamics (MD) simulations supplied solid data and visual images to estimate the driving forces for the self-assembly process of the carrier-free nanoparticles as primary hydrophobic interactions (π-π stacking) and subordinate hydrogen bonds. Conclusively, the above self-assembled carrier-free nanoparticles represented a promising synergistic anticancer strategy capable of maximal therapeutic efficacy and minimal systemic toxicity. Moreover, the application of thermodynamic method together with MD simulations in the investigation of NPs self-assembly process also provided new ideas for the assembly mechanism exploration of more complicated nanodrug delivery system.

Carrier-Free, Dual-Functional Nanorods Via Self-Assembly Of Pure Drug Molecules For Synergistic Chemo-Photodynamic Therapy.

BACKGROUND: The combination of chemo-photodynamic therapy based on nano-technology has emerged as a preferable and promising measure for synergetic antitumor therapy. PURPOSE: The aim of this study was expected to overcome most of the safety concerns from nano-carriers and improve the chemo-photodynamic synergistic antitumor efficacy. METHODS: Herein, we reported a facile and effective approach based on the self-assembly of chemotherapeutic agent 10-hydroxycamptothecin (HCPT) and photosensitizer chlorin e6 (Ce6) for preparing stably dual-functional nanorods (NRs). RESULTS: The chemical thermodynamic parameters obtained from isothermal titration calorimeter (ITC) and the microcosmic configuration snapshots acquired by molecular dynamics (MD) simulations verified that HCPT and Ce6 molecules tended to assemble with each other through various intermolecular forces. The as-prepared HCPT/Ce6 NRs possessed a relatively uniform size of around 165 nm and zeta potential of about -29 mV, together with good stability in aqueous solution and freeze-dried state. In addition, both the extra- and intracellular reactive oxygen species (ROS) generation capacity of the NRs under laser irradiation was significantly enhanced compared with Ce6 injections. Moreover, the dual-functional HCPT/Ce6 NRs exhibited a substantial in vitro/in vivo synergistic antitumor efficacy under laser irradiation due to the integration of the two therapeutic modalities into one drug delivery system. Besides, no obvious hepatic or renal toxicity was observed in the NRs treatment groups. CONCLUSION: Taken together, HCPT/Ce6 NRs demonstrated a powerful efficacy in chemo-photodynamic therapy for breast cancer. Therefore, the carrier-free dual-functional NRs prepared in a facile and effective strategy might give inspiration for the development of combined antitumor therapy.

An organic solvent-free technology for the fabrication of albumin-based paclitaxel nanoparticles for effective cancer therapy.

Organic solvents have been reported to exert certain influence on the structure and drug loading efficiency of albumin. It is urgent to develop organic solvent-free albumin-based paclitaxel nanoparticles for effective anticancer therapy. In this study, novel PTX liposome-albumin composite nanoparticles (Lip-PTX/BSA NPs) aimed at avoiding the direct contact of albumin with toxic organic solvents and enhancing the colloidal stability of the formulation were prepared. To methodically evaluate the impacts of multifarious factors on the critical characteristics of the nanoparticles, Box-Behnken design was applied in the formulation optimized process. Ratio of drug-phosphatidylcholine (EPC), ratio of drug-BSA and pH of the media were chosen as the independent variables, while particle size and drug-loading content (DLC) loss rate were applied as the selected response variables. A quadratic model fitted best to describe the data with maximal lack-of-fit p-value and minimum sequential p-value. Three-dimension surface figures were utilized to describe the correlation of independent variables with response variables. Optimized formulation of the nanoparticles with size of 116.2 ±â€¯2.0 nm and zeta potential of -18.4 ±â€¯1.01 mV were obtained with a high encapsulation efficiency of 99.8%. PTX was involved physical interaction with the excipient during the preparation process of the nanoparticles. The release of PTX from Lip-PTX/BSA NPs exhibited a sustained release manner compared to albumin-bound PTX (nab-PTX) and Taxol. Besides, Lip-PTX/BSA NPs presented enhanced in vitro cytotoxicity against 4T1 cells due to highly nonspecific internalization in the cytoplasm. Simultaneously, Lip-PTX/BSA NPs showed effective in vivo antitumor efficacy against 4T1 bearing BALB/c mice, while no apparent adverse effect was observed by histological section and blood biochemical analysis. In conclusion, the novel Lip-PTX/BSA NPs could be applied as a promising drug delivery system for PTX to exert efficient cancer curative effects in clinic.

Effect of plasticizers on manufacturing ritonavir/copovidone solid dispersions via hot-melt extrusion: Preformulation, physicochemical characterization, and pharmacokinetics in rats.

In this study, novel ritonavir solid dispersion (RTV SD) formulations were prepared with copovidone (PVPVA 64) and optimized plasticizers via hot-melt extrusion (HME) at different extrusion temperature to evaluate the effect of plasticizers on the process of HME. The optimized drug-loading content of RTV SD formulations was around 15% and RTV was converted to the amorphous state and integrated through physical interactions (possibly hydrogen bonding) with the polymeric carrier. Using Span 20 or HSPC as plasticizer, the HME extrusion temperature of RTV SD formulations suggested a decrease of 10 °C or 20 °C. Furthermore, the in vitro release and the in vivo pharmacokinetics analyses both showed that RTV SD formulations using Span 20 or HSPC as plasticizer possessed better release profiles and bioavailability over RTV bulk powder but showed equal physicochemical characteristics compared to RTV SD formulations without plasticizer. According to the increased drug solubility, enhanced dissolution profiles, superior bioavailability, but decreased extrusion temperature in HME process, the RTV SD formulation using HSPC as plasticizer could be potentially applied in the clinic as an efficient drug delivery system, and HSPC is recommended as an efficient plasticizer for manufacturing RTV SD formulations via HME.

Effect of HPMCAS on recrystallization inhibition of nimodipine solid dispersions prepared by hot-melt extrusion and dissolution enhancement of nimodipine tablets.

In current study, a novel nimodipine solid dispersion (NM-SD) was prepared by hot-melt extrusion (HME) with Hypromellose methylcellulose acetate succinate (H type and fine grades, HPMCAS-HF) for its excellent recrystallization inhibition effects. NM was confirmed to exist as an amorphous state in NM-SD by differential scanning calorimetry (DSC), powder X-ray diffraction (PXRD), hot stage microscopy (HSM) and scanning electron micrographs (SEM). FT-IR analysis illustrated hydrogen bond interaction between drugs and excipients in NM-SD. The release behavior of NM-SD tablets was investigated in the dissolution medium of pH 6.8 for the in vitro study, which showed that the release of nimodipine could be realized in vitro without recrystallization within two hours. The in vivo pharmacokinetic profiles study in Sprague-Dawley rats was also determined. It was obvious that the Cmax value of NM-SD tablets made by dry granulation was slightly higher than Nimotop®, while the area under the curve, AUC(0-t) exhibited no significant difference between them. In conclusion, the solubility of NM and dissolution rate of NM-SD tablets were greatly improved by HME due to the recrystallization inhibition characteristic of HPMCAS-HF.