Sensitive Inexpensive HPLC Determination of Novel Anticancer Combination in Nanoparticles and Rat Plasma: Pharmacokinetic Application.

Two high-performance liquid chromatography-diode array detection methods have been developed and validated for the simultaneous quantification of genistein (GNS) and all trans retinoic acid (ATRA) as a novel anticancer combination therapy in their co-formulated nanoparticles and in rat plasma. Separation was performed on C18 column (250 × 4.6 mm, 5 µm) using celecoxib as internal standard. A mobile phase containing acetonitrile and water adjusted to pH 3 using 1% trifluoroacetic acid was delivered in gradient elution modes with time programmed UV detection. For extraction of the drugs and the internal standard from rat plasma, liquid- liquid extraction was applied. The proposed methods were validated as per International Conference on Harmonisation (ICH) guidelines (in the range 0.1-10 µg/mL for analysis of GNS and ATRA in nanoparticles) or according to Food and Drug Administration (FDA) guidance on bioanalytical method validation (in the range 0.025-20 µg/mL for analysis of GNS and ATRA in rat plasma). Pharmacokinetic study in six rats was performed following intravenous (IV) administration of a single dose of 0.5 mg/Kg of GNS and ATRA. The drugs' concentrations were measured up to 24 hours, and different pharmacokinetic parameters were calculated. The obtained parameters were comparable with the reported values for IV administration of each drug alone in rats. This confirms the applicability of the proposed method in monitoring the levels of the two drugs in vivo following their coadministration and indicating that the two drugs could be coadministered as a promising novel combination therapy for the treatment of lung cancer without great alteration in their pharmacokinetic parameters compared with their individual IV administration.

Inhalable Dual-Targeted Hybrid Lipid Nanocore-Protein Shell Composites for Combined Delivery of Genistein and All-Trans Retinoic Acid to Lung Cancer Cells.

Localized pulmonary delivery of anticancer agents to lungs has proven to be pioneering approach for lung cancer therapy. Hybrid lipid nanocore-protein shell nanoparticles (HLPNPs) coloaded with all-trans retinoic acid (ATRA) and genistein (GNS) were prepared via sequential solvent evaporation followed by nanoprecipitation of zein shell onto the lipid core. The outer protein shell of HLPNPs provided additional drug reservoir for encapsulation of ATRA/stearyl amine ion pair and enabled dual tumor-targeting with biotin and ATRA. Enhanced uptake and cytotoxic activity of HLPNPs against A549 lung cancer cells was confirmed. To improve their deep lung deposition, dual-targeted drug-loaded HLPNP nanocomposites were fabricated. The nanocomposites prepared using mannitol/HPßCD/leucine demonstrated favorable aerosolization (MMAD = 2.47 µm and FPF = 70.81%). In vivo, the inhalable nanocomposites were superior to aerosolized or i.v. nanoparticle suspension against lung carcinoma bearing mice. Overall, inhalable dual-targeted HLPNPs nanocomposites provided localized codelivery of GNS and ATRA for lung cancer therapy.

Inhalable Lactoferrin/Chondroitin-Functionalized Monoolein Nanocomposites for Localized Lung Cancer Targeting.

Localized drug delivery to lung cancer can overcome the limitations of systemic nanocarriers including low drug amounts reaching lung tissues and severe off-target toxicity. The current work presented novel inhalable nanocomposites as noninvasive platforms for lung cancer therapy. Nanoparticulate liquid crystals (LCNPs) based on monoolein were developed for synergistic co-encapsulation of the cytotoxic chemotherapeutic drug, pemetrexed, and the phytoherbal drug, resveratrol (PEM-RES-LCNPs). For active tumor targeting, lactoferrin (LF) and chondroitin sulfate (CS), natural polymers with intrinsic tumor-targeting capabilities, were exploited to functionalize the surface of LCNPs using a layer-by-layer (LbL) self-assembly approach. To maximize their deep lung deposition, LF/CS-coated PEM-RES-LCNPs were then microencapsulated within various carriers to obtain inhalable nanocomposites via spray-drying techniques. The inhalable dry powder nanocomposites prepared using a mannitol-inulin-leucine (1:1:1 wt) mixture displayed superior in vitro aerosolization performance (2.72 µm of MMAD and 61.6% FPF), which ensured deep lung deposition. In lung cancer-bearing mice using urethane as a chemical carcinogen, the inhalable LF/CS-coated PEM-RES-LCNP nanocomposites showed superior antitumor activity as revealed by a considerable decrease of the average lung weight, reduced number and diameter of cancerous lung foci, decreased expression of VEGF-1, and increased expression of active caspase-3 as well as reduced Ki-67 expression compared to the spray-dried free PEM/RES powder mixture and positive control. Moreover, the in vivo fluorescence imaging confirmed successful lung deposition of the inhalable nanocomposites. Conclusively, the inhalable liquid crystalline nanocomposites elaborated in the current work could open new avenues for noninvasive lung cancer treatment.

Multicompartmental lipid-protein nanohybrids for combined tretinoin/herbal lung cancer therapy.

Aim: Multicompartmental lipid-protein nanohybrids (MLPNs) were developed for combined delivery of the anticancer drugs tretinoin (TRE) and genistein (GEN) as synergistic therapy of lung cancer. Materials & methods: The GEN-loaded lipid core was first prepared and then coated with TRE-loaded zein shell via nanoprecipitation. Results: TRE/GEN-MLPNs demonstrated a size of 154.5 nm. In situ ion pair formation between anionic TRE and the cationic stearyl amine improved the drug encapsulation with enhanced stability of MLPNs. TRE/GEN-coloaded MLPNs were more cytotoxic against A549 cancer cells compared with combined free GEN/TRE. In vivo, lung cancer bearing mice treated with TRE/GEN-MLPNs displayed higher apoptotic caspase activation compared with mice-treated free combined GEN/TRE. Conclusion: TRE/GEN-MLPNs might serve as a promising parenteral nanovehicles for lung cancer therapy.

Liquid crystalline assembly for potential combinatorial chemo-herbal drug delivery to lung cancer cells.

BACKGROUND: Lung cancer is the most common cancer and the leading cause of total deaths worldwide. Its classified into two major types including non-small cell lung carcinoma (NSCLC) and small cell lung carcinoma (SCLC) based on the origin of abnormal lung cells as well as the smoking status of the patient. NSCLC is the most common and aggressive type of lung cancer representing 80%-85% of all cases. PURPOSE: The aim of the study was to present lyotropic liquid crystalline nanoparticles (LCNPs) as promising carriers for co-delivery of the chemotherapeutic agent, pemetrexed (PMX) and the herbal drug, resveratrol (RSV) for effective lung cancer management. METHODS: The proposed PMX-RSV-LCNPs were prepared by hydrotrope method. Hydrophobic ion pairing with cetyl trimethyl ammonium bromide (CTAB) was implemented to increase the encapsulation efficiency of the hydrophilic PMX up to 95%±3.01%. RESULTS: The tailored PMX-RSV-LCNPs exhibited a particle size of 173±0.26 nm and biphasic release pattern with a relatively initial burst release within first 3-4 hour followed by sustained release up to 24 hours. Moreover, PMX-RSV-LCNPs manifested superior concentration and time dependent cytotoxicity profile against A549 lung cancer cells with IC50 4.0628 µg/mL. Besides, the enhanced cellular uptake profile based on bioadhesive properties of glyceryl monoolein (GMO) as well as energy independent (cholesterol dependent) pattern. In-vivo evaluations against urethane induced lung cancer bearing mice demonstrated the potentiality of PMX-RSV-LCNPs in tumor growth inhibition via inhibition of angiogenesis and induction of apoptosis. The results were supported by histopathological analysis and immunohistochemical Ki67 staining. Moreover, PMX-RSV-LCNPs displayed a promising safety profile via attenuating nephro- and hepatotoxicity. CONCLUSION: PMX-RSV-LCNPs elaborated in the current study hold a great promise for lung cancer treatment.

Inhalable particulate drug delivery systems for lung cancer therapy: Nanoparticles, microparticles, nanocomposites and nanoaggregates.

There is progressive evolution in the use of inhalable drug delivery systems (DDSs) for lung cancer therapy. The inhalation route offers many advantages, being non-invasive method of drug administration as well as localized delivery of anti-cancer drugs to tumor tissue. This article reviews various inhalable colloidal systems studied for tumor-targeted drug delivery including polymeric, lipid, hybrid and inorganic nanocarriers. The active targeting approaches for enhanced delivery of nanocarriers to lung cancer cells were illustrated. This article also reviews the recent advances of inhalable microparticle-based drug delivery systems for lung cancer therapy including bioresponsive, large porous, solid lipid and drug-complex microparticles. The possible strategies to improve the aerosolization behavior and maintain the critical physicochemical parameters for efficient delivery of drugs deep into lungs were also discussed. Therefore, a strong emphasis is placed on the approaches which combine the merits of both nanocarriers and microparticles including inhalable nanocomposites and nanoaggregates and on the optimization of such formulations using the proper techniques and carriers. Finally, the toxicological behavior and market potential of the inhalable anti-cancer drug delivery systems are discussed.

Crystallization of progesterone for pulmonary drug delivery.

The purpose of this study is to investigate the suitability of the crystallization process to produce microcrystals of progesterone for respiratory drug delivery. Crystallization of progesterone was carried out from water-isopropanol (IPA) mixture. The antisolvent (water) was added at two different addition rates (10 and 100 mL/min). The mass percentage of antisolvent was varied between (50% and 75%), and the initial drug concentration was adjusted at (0.5 and 1 g/L). The effect of crystallization method (antisolvent precipitation or combined cooling and antisolvent) was also examined. These operating conditions were investigated in a 2(4) factorial design in an effort to optimize the process. Different solid-state and surface characterization techniques were applied in conjunction with measurements of powder flow properties using aerodynamic particle sizer (APS). Powder dispersibility and aerosol performance were analyzed using Anderson Cascade Impactor (ACI). Antisolvent addition rate, initial drug concentration and dynamic solvent composition are shown to have a significant effect on the aerosol characteristics of progesterone microcrystals. An increase of 38.73% in the fine particle fraction (FPF) was demonstrated for some powders produced by combined cooling and antisolvent crystallization. In conclusion, it was possible to control particle size and hence, pulmonary deposition using process parameters alone, and produce particles with a narrow particle size distribution and a mean particle size of 5 microm with nearly no particles larger than 10 microm by direct crystallization. The suitability of deep pulmonary deposition was proved by the platelet-like morphology of processed microcrystals and greater surface-to-volume ratio than spherical particles.