Shiyan Guo

Intestinal mucosa permeability following oral insulin delivery using core shell corona nanolipoparticles

Chitosan nanoparticles (NC) have excellent capacity for protein entrapment, favorable epithelial permeability, and are regarded as promising nanocarriers for oral protein delivery. Herein, we designed and evaluated a class of core shell corona nanolipoparticles (CSC) to further improve the absorption through enhanced intestinal mucus penetration. CSC contains chitosan nanoparticles as a core component and pluronic F127-lipid vesicles as a shell with hydrophilic chain and polyethylene oxide PEO as a corona. These particles were developed by hydration of a dry pluronic F127-lipid film with NC suspensions followed by extrusion. Insulin nested inside CSC was well protected from enzymatic degradation. Compared with NC, CSC exhibited significantly higher efficiency of mucosal penetration and, consequently, higher cellular internalization of insulin in mucus secreting E12 cells. The cellular level of insulin after CSC treatment was 36-fold higher compared to treatment with free insulin, and 10-fold higher compared to NC. CSC significantly facilitated the permeation of insulin across the ileum epithelia, as demonstrated in an ex vivo study and an in vivo absorption study. CSC pharmacological studies in diabetic rats showed that the hypoglycemic effects of orally administrated CSC were 2.5-fold higher compared to NC. In conclusion, CSC is a promising oral protein delivery system to enhance the stability, intestinal mucosal permeability, and oral absorption of insulin.

Dual-functional liposome for tumor targeting and overcoming multidrug resistance in hepatocellular carcinoma cells

The purpose of this study was to design and evaluate the dual-functional liposome (LPG) with synthetic polymeric nano-biomaterial (Gal-P123) that targets cancer cells and reverses multidrug resistance (MDR) in hepatocellular carcinoma (HCC) cells. The mitoxantrone (MX) loaded LPG (MX-LPG) was about 100 nm in diameter, spherically shaped, and had an encapsulation efficiency of 97.3%. The cytotoxicity and cellular uptake of MX-LPG were evaluated in HCC Huh-7 cells. BCRP-overexpressing MDCKII/BCRP cells were used to certify the inhibitory effect of LPG on drug efflux transporter. Compared with MX, MX-LPG had 2.3-fold higher cytotoxicity in Huh-7 cells and a 14.9-fold increase in cellular MX accumulation in MDCKII/BCRP cells. The pharmacokinetic study in rats showed that LPG significantly prolonged the circulation time and enhanced the bioavailability of MX. Moreover, MX-LPG increased antitumor activity and improved selectivity in BALB/c mice bearing orthotopic xenograft HCC tumors.

Advances in the transepithelial transport of nanoparticles

The intestinal epithelium represents a barrier to the delivery of nanoparticles (NPs). It prevents intact NPs from efficiently crossing the mucosa to access the circulation, thus limiting the successful application of NP-based oral drug delivery. Recent advances in nanotechnology have provided promising solutions to this challenge. This review describes the potential intestinal absorption pathways of NPs, including the transenterocytic pathway, paracellular pathway and M-cell-mediated pathway. NP properties that influence transcytosis are summarized; and the biodistribution of NPs after oral absorption is described and the future prospects of novel NPs are explored.

Preparation of redispersible liposomal dry powder using an ultrasonic spray freeze-drying technique for transdermal delivery of human epithelial growth factor

In this work, an ultrasonic spray freeze-drying (USFD) technique was used to prepare a stable liposomal dry powder for transdermal delivery of recombinant human epithelial growth factor (rhEGF). Morphology, particle size, entrapment efficiency, in vitro release, and skin permeability were systematically compared between rhEGF liposomal dry powder prepared using USFD and that prepared using a conventional lyophilization process. Porous and spherical particles with high specific area were produced under USFD conditions. USFD effectively avoided formation of ice crystals, disruption of the bilayer structure, and drug leakage during the liposome drying process, and maintained the stability of the rhEGF liposomal formulation during storage. The reconstituted rhEGF liposomes prepared from USFD powder did not show significant changes in morphology, particle size, entrapment efficiency, or in vitro release characteristics compared with those of rhEGF liposomes before drying. Moreover, the rhEGF liposomal powder prepared with USFD exhibited excellent enhanced penetration in ex vivo mouse skin compared with that for powder prepared via conventional lyophilization. The results suggest that ultrasonic USFD is a promising technique for the production of stable protein-loaded liposomal dry powder for application to the skin.

Effect of poly (ethylene oxide)-poly (propylene oxide)-poly (ethylene oxide) micelles on pharmacokinetics and intestinal toxicity of irinotecan hydrochloride: potential involvement of breast cancer resistance protein (ABCG2)

Objectives  Intestinal toxicity and low levels of systemic drug exposure are among the major problems associated with tumour therapy. We have developed poly (ethylene oxide)‐poly (propylene oxide)‐poly (ethylene oxide) (PEO‐PPO‐PEO) micelles loaded with irinotecan hydrochloride (CPT‐11) hoping to decrease CPT‐11‐induced intestinal toxicity while increasing its systemic exposure. In addition, we have investigated the potential involvement of breast cancer resistance protein (BCRP) in biliary excretion, pharmacokinetics, and intestinal toxicity of CPT‐11.

Thermosensitive Liposomal Co-delivery of HSA-paclitaxel and HSA-ellagic Acid Complexes for Enhanced Drug Perfusion and Efficacy Against Pancreatic Cancer.

Fibrotic stroma and tumor-promoting pancreatic stellate cells (PSCs), critical characters in the pancreatic ductal adenocarcinoma (PDA) microenvironment, promote a tumor-facilitating environment that simultaneously prevents drug penetration into tumor foci and stimulates tumor growth. Nab-PTX, a human serum albumin (HSA) nanoparticle of paclitaxel (PTX), indicates enhanced matrix penetration in PDA probably due to its small size in vivo and high affinity of HSA with secreted protein acidic and rich in cysteine (SPARC), overexpressed in the PDA stroma. However, this HSA nanoparticle shows poor drug blood retention because of its weak colloidal stability in vivo, thus resulting in insufficient drug accumulation within tumor. Encapsulating HSA nanoparticles into the internal aqueous phase of ordinary liposomes improves their blood retention and the following tumor accumulation, but the large 200 nm size and shielding of HSA in the interior might make it difficult for this hybrid nanomedicine to penetrate the fibrotic PDA matrix and promote bioavailability of the payload. In our current work, we prepared ∼9 nm HSA complexes with an antitumor drug (PTX) and an anti-PSC drug (ellagic acid, EA), and these two HSA-drug complexes were further coencapsulated into thermosensitive liposomes (TSLs). This nanomedicine was named TSL/HSA-PE. The use of TSL/HSA-PE could improve drug blood retention, and upon reaching locally heated tumors, these TSLs can rapidly release their payloads (HSA-drug complexes) to facilitate their further tumor accumulation and matrix penetration. With superior tumor accumulation, impressive matrix penetration, and simultaneous action upon tumor cells and PSCs to disrupt PSCs-PDA interaction, TSL/HSA-PE treatment combined with heat exhibited strong tumor growth inhibition and apoptosis in vivo.

Rapid transport of deformation-tuned nanoparticles across biological hydrogels and cellular barriers

To optimally penetrate biological hydrogels such as mucus and the tumor interstitial matrix, nanoparticles (NPs) require physicochemical properties that would typically preclude cellular uptake, resulting in inefficient drug delivery. Here, we demonstrate that (poly(lactic-co-glycolic acid) (PLGA) core)-(lipid shell) NPs with moderate rigidity display enhanced diffusivity through mucus compared with some synthetic mucus penetration particles (MPPs), achieving a mucosal and tumor penetrating capability superior to that of both their soft and hard counterparts. Orally administered semi-elastic NPs efficiently overcome multiple intestinal barriers, and result in increased bioavailability of doxorubicin (Dox) (up to 8 fold) compared to Dox solution. Molecular dynamics simulations and super-resolution microscopy reveal that the semi-elastic NPs deform into ellipsoids, which enables rotation-facilitated penetration. In contrast, rigid NPs cannot deform, and overly soft NPs are impeded by interactions with the hydrogel network. Modifying particle rigidity may improve the efficacy of NP-based drugs, and can be applicable to other barriers.Penetration of the mucus and tumor interstitial matrix is an important consideration for drug delivery devices. Here, the authors report on a study into the optimization of rigidity for the transport of nanoparticles through biological hydrogels using core-shell polymer-lipid nanoparticles.

A poly-L-glutamic acid functionalized nanocomplex for improved oral drug absorption

Poor permeability of the intestinal epithelium limits the oral absorption of many drugs. Here, a poly-l-glutamic acid (PGA)-based functional ternary nanocomplex (TC) is reported for enhancing the intestinal absorption of poorly permeable drug doxorubicin hydrochloride (Dox·HCl). The particle size and zeta potential of TC were 189.3 ± 13.7 nm and -29.1 ± 7.4 mV, respectively. The TC was shown to be more stable under simulated gastrointestinal changing pH or electrolyte content conditions than the binary nanocomplex Dox·HCl/PGA. Cellular uptake and the apparent permeability coefficient value (Papp) of the TC were determined to be 5.2- and 4.6-fold higher than that of Dox·HCl solutions, respectively. Mechanistic studies showed that active endocytosis caused by specific interactions between γ-glutamyl terminal groups of PGA and membrane-bound γ-glutamyl transferase contributed much to the TC-dependent Dox·HCl absorption. Studies on the rat model also demonstrated the highest efficiency for Dox·HCl absorption by the TC throughout the intestinal tract, with 2.6- and 4.2-fold higher Cmax and AUC0-24h values compared to Dox·HCl solutions. In conclusion, the TC is a promising carrier for improving Dox·HCl intestinal absorption, and the rational design of carriers with functional polymer PGA could implement the efficient active absorption of poorly permeable drugs.