Airway epithelial-targeted nanoparticle reverses asthma in inhalation therapy.

Despite extensive research on corticosteroids for treating asthma, their short residence time in the lungs has limited their therapeutic effects in vivo. Nanoparticles have been widely investigated for inhaled drug delivery due to their potential benefits in prolonging drugs' residence time in the lungs. However, the retention of nanoparticles may be limited by mucus and ciliated epithelium clearance mechanisms in the airway. Herein, we anchored a neonatal-Fc-receptor-targeted peptide (FcBP) onto "mucus-penetrating" polyethylene glycol (PEG) nanoparticles (PEG-NP). Interestingly, the mucus-permeability of PEG-NP was not impaired by FcBP-functionalization. Moreover, FcBP modification enhanced cellular internalization and exocytosis via specific receptor-mediated processes, which subsequently ameliorated transepithelial transport and prolonged pulmonary retention. Importantly, after loading dexamethasone, FcBP-functionalization could effectively help nanoparticles cross the airway epithelial layer and be endocytosed by inflammatory cells, resulting in a marked decrease in inflammatory cytokines. Finally, FcBP modification significantly enhanced the therapeutic effect of dexamethasone-loaded nanoparticles in asthma mice. This study demonstrates that FcBP-functionalized PEG-NP can overcome multiple obstacles in the airway to prolong the pulmonary retention of drugs, providing a promising strategy for inhalation therapy.

Disease-specific protein corona formed in pathological intestine enhances the oral absorption of nanoparticles.

Protein corona (PC) has been identified to impede the transportation of intravenously injected nanoparticles (NPs) from blood circulation to their targeted sites. However, how intestinal PC (IPC) affects the delivery of orally administered NPs are still needed to be elucidated. Here, we found that IPC exerted "positive effect" or "negative effect" depending on different pathological conditions in the gastrointestinal tract. We prepared polystyrene nanoparticles (PS) adsorbed with different IPC derived from the intestinal tract of healthy, diabetic, and colitis rats (H-IPC@PS, D-IPC@PS, C-IPC@PS). Proteomics analysis revealed that, compared with healthy IPC, the two disease-specific IPC consisted of a higher proportion of proteins that were closely correlated with transepithelial transport across the intestine. Consequently, both D-IPC@PS and C-IPC@PS mainly exploited the recycling endosome and ER-Golgi mediated secretory routes for intracellular trafficking, which increased the transcytosis from the epithelium. Together, disease-specific IPC endowed NPs with higher intestinal absorption. D-IPC@PS posed "positive effect" on intestinal absorption into blood circulation for diabetic therapy. Conversely, C-IPC@PS had "negative effect" on colitis treatment because of unfavorable absorption in the intestine before arriving colon. These results imply that different or even opposite strategies to modulate the disease-specific IPC need to be adopted for oral nanomedicine in the treatment of variable diseases.

Butyrate Modification Promotes Intestinal Absorption and Hepatic Cancer Cells Targeting of Ferroptosis Inducer Loaded Nanoparticle for Enhanced Hepatocellular Carcinoma Therapy.

Sorafenib is an oral-administered first-line drug for hepatocellular carcinoma (HCC) treatment. However, the therapeutic efficacy of sorafenib is relatively low. Here, an oral delivery platform that increases sorafenib uptake by HCC and induces potent ferroptosis is designed. This platform is butyrate-modified nanoparticles separately encapsulated with sorafenib and salinomycin. The multifunctional ligand butyrate interacts with monocarboxylate transporter 1 (MCT-1) to facilitate transcytosis. Specifically, MCT-1 is differentially expressed on the apical and basolateral sides of the intestine, highly expressed on the surface of HCC cells but lowly expressed on normal hepatocytes. After oral administration, this platform is revealed to boost transepithelial transport effectively and continuously in the intestine, drug accumulation in the liver, and HCC cell uptake. Following drug release in cancer cells, sorafenib depletes glutathione peroxidase 4 and glutathione, consequently initiating ferroptosis. Meanwhile, salinomycin enhances intracellular iron and lipid peroxidation, thereby accelerating ferroptosis. In vivo experiments performed on the orthotopic HCC model demonstrate that this combination strategy induces pronounced ferroptosis damage and ignites a robust systemic immune response, leading to the effective elimination of tumors and establishment of systemic immune memory. This work provides a proof-of-concept demonstration that an oral delivery strategy for ferroptosis inducers may be beneficial for HCC treatment.

Increasing stiffness promotes pulmonary retention of ligand-directed dexamethasone-loaded nanoparticle for enhanced acute lung inflammation therapy.

Inhaled nanoparticles (NPs) need to penetrate the bronchial mucosa to deliver drug payloads deeply in the lung for amplified local therapy. However, the bronchial mucociliary barrier eliminates NPs rapidly, which considerably limits their mucosal penetration. In this study, we find that surface ligand modification and stiffness adjustment of NPs contribute to the significantly enhanced bronchial mucosal absorption and pulmonary retention of inhaled drugs. We utilize neonatal Fc receptor ligand (FcBP) to modify the rationally designed low stiffness NPs (Soft-NP) and high stiffness NPs (Stiff-NP) to target bronchial mucosa. In an acute lung inflammation rat model, after intranasal administration with dexamethasone-loaded NPs, Stiff-NP endowed with FcBP displays superior therapeutic effects. The in vitro data demonstrate that the promotion effect of FcBP to bronchial mucosal absorption of Stiff-NP dominates over Soft-NP. This could be attributed to the higher affinity between ligand-receptor when incorporating FcBP on the Stiff-NP surface. Meanwhile, high stiffness modulates more actin filaments aggregation to mediate endocytosis, along with strengthened Ca2+ signal to enhance exocytosis. Conclusively, we highlight that FcBP-modified NPs with higher stiffness would be a potential pulmonary drug delivery system.

Coordination of rigidity modulation and targeting ligand modification on orally-delivered nanoparticles for the treatment of liver fibrosis.

Although the individual role of ligand modification or rigidity modulation on oral administration of nanoparticle (NP) has been investigated, how they mutually affect each other remains to be elucidated. Here, we fabricated different rigidity NP with or without surface decoration of FcBP, a neonatal Fc receptor domain-binding peptide. In vitro studies showed that, without FcBP modification, stiff NP had higher transcytosis efficiency across the epithelium than softer NP, due to the different endocytosis mechanisms, intracellular trafficking routes, and exocytosis rate. Notably, after FcBP modification, such difference was narrowed, in a manner that was more favorable for softer NP to "catch up" with stiff NP, suggesting ligand modification was more conducive to exert transcytosis-promoting efficacy on softer NP. In vivo experiments demonstrated that, for ligand-free NP, high rigidity was required for efficient oral absorption and liver distribution. Further FcBP modification decreased that "rigidity threshold", and expanded the feasible rigidity range from stiff NP to softer NP. Upon oral administration, FcBP-modified dexamethasone-loaded softer NP achieved a therapeutic efficacy comparable with stiff NP on alleviating liver fibrosis. Collectively, our study highlighted the necessity of coordinating ligand modification and rigidity modulation for oral drug delivery.

Complying with the physiological functions of Golgi apparatus for secretory exocytosis facilitated oral absorption of protein drugs.

Intestinal epithelial cells are the primary biological barriers for orally administrated nano-formulations and the delivered protein drugs. Thereinto, besides the cellular uptake, intracellular trafficking pathway and the related exocytosis are of great importance to the trans-epithelial transport of drug-loaded NPs. Herein, inspired by the physiological functions of Golgi apparatus for secreting proteins out of cells, Golgi localization-related amino acid l-cysteine (Cys) was modified on the surface of NPs to see whether and how this modification could guide the Golgi pathway-related transport and facilitate the exocytosis of drug-loaded NPs. Meanwhile, cell-penetrating peptide octa-arginine (R8) was co-modified to increase the cellular uptake. The proportion of R8 and Cys modification was explored to get the best effect of endocytosis and exocytosis of NPs. As a result, 25%R8 + 75%Cys NPs with most Cys modification showed efficient transcytosis with the highest transcytosis/endocytosis ratio (0.87). Interestingly, exocytosis mechanism studies indicated that they trafficked through the Golgi secretory pathway and bypassed lysosomes due to Cys modification. The detailed Golgi position mechanism studies further suggested that the thiol group from Cys was important for mediating Golgi transport. In particular, competitive inhibition studies demonstrated that Cys-modified NPs were more conducive to their exocytosis after being transported through the Golgi secretory pathway. We proved that cargos transported via Golgi apparatus tended to be trafficked out of the cells and avoid degradation, which contributed to the transcytosis of 25%R8 + 75%Cys NPs in vitro. Inspiringly, compared with unmodified NPs, 25%R8 + 75%Cys NPs also exhibited promoted intestinal penetration and oral absorption in vivo. Oral delivery of insulin-loaded 25%R8 + 75%Cys NPs showed stronger hypoglycemic effects in diabetic rats. In summary, this work provides a strategy for complying with the physiological functions of Golgi apparatus for secreting to facilitate the exocytosis of NPs, thus further improving the oral absorption of loaded protein drugs.

pH-dependent reversibly activatable cell-penetrating peptides improve the antitumor effect of artemisinin-loaded liposomes.

Artemisinin (ART) is well known as an antimalarial drug, and it can also be used to treat inflammation as well as cancer. Although many researchers have reported the antitumor activity of ART, most of these studies were investigated in vitro. In addition, ART is sparingly soluble in water, limiting its clinical relevance in drug development. Based on the data from our preliminary study, ART is not cytotoxic at low micromolar concentrations. Thus, we hypothesized that smart nanocarriers are beneficial for not only increasing the solubility of ART but also elevating the concentration of the drug at the target, thereby inducing the ideal antitumor effect. In this article, a reversibly activatable cell-penetrating peptide ((HE)10-G5-R6 or HE-R6) was introduced to modify artemisinin (ART)-loaded liposomes (ART-Lip-HE-R6) against tumors, and in vitro and in vivo performance were investigated. ART-Lip-HE-R6 exhibited sustained release under different pH conditions. The internalization and cytotoxicity of liposomes were enhanced at low pH, i.e., 6.5, after modification with HE-R6 versus nonmodified liposomes. Moreover, a longer retention time in tumors could be observed in the ART-Lip-HE-R6 group, followed by higher efficiency of tumor suppression. In conclusion, Lip-HE-R6 might be a promising delivery system for ART in cancer therapy.

Redox-sensitive polyglutamic acid-platinum(IV) prodrug grafted nanoconjugates for efficient delivery of cisplatin into breast tumor.

Targeting cisplatin to the sites of action and decreasing its side effects are still major challenges. Here, we introduced a polyglutamic acid-platinum(IV) prodrug nanoconjugates (γ-PGA-CA-Pt(IV)) constructed by polyglutamic acid and modified platinum(IV) prodrug to reserve the anti-tumor efficacy of cisplatin with decreased side effects. We describe the synthesis, physico-chemical characterization, and redox- and pH-sensitive releasing behavior of the nanoconjugate. In vitro studies revealed that, when incubated with glutathione in advance, the γ-PGA-CA-Pt(IV) nanoconjugate induced significant apoptosis in human breast carcinoma MCF-7 cells. From in vivo antitumor efficacy evaluation, the γ-PGA-CA-Pt(IV) nanoconjugate obviously improved the survival rate of tumor-bearing mice with inhibition of the tumor growth compared with cisplatin. Meanwhile, the nanoconjugates showed remarkable improved safety profile than the free cisplatin.

Highly loaded deoxypodophyllotoxin nano-formulation delivered by methoxy polyethylene glycol-block-poly (D,L-lactide) micelles for efficient cancer therapy.

Cancer is a kind of malignant diseases that threatens human health and the research application of anti-tumor drug therapeutics is growingly always been focused on. Many new compounds with great anticancer activity were synthesized but cannot be hard to be developed into clinical use due to its poor water solubility. Deoxypodophyllotoxin (DPT) is just an example. We develop lyophilized Deoxypodophyllotoxin (DPT) loaded polymeric micelles using methoxy polyethylene glycol-block-Poly (D, L-lactide) (mPEG-PLA). DPT-PM freeze-dried powder was successfully prepared using optimized formulation. mPEG-PLA was added to hydration media before hydrating as cryoprotectants. The freeze-dried powder exhibited white pie-solid without collapsing, and the particle size of DPT-PM reconstituted with water was about 20-35 nm. The entrapment efficiency of the reconstituted solution was 98%, which shows no differences with the micelles before lyophilization. In-vitro cytotoxicity and cellular uptake studies showed that DPT-PM has a higher degree of cytotoxicity comparing with DPT and mPEG-PLA micelles and uptake of mPEG-PLA was concentration and time-dependent. In vivo characterization of DPT-PM was done for pharmacokinetics behaviors, antitumor activity and safety. The obtained results showed significant improvement in plasma clearance bioavailability (p <0.05) and prolonged blood circulation time comparing with DPT-HP-ß-CD. Moreover, mPEG-PLA micelles had a better degree of anti-tumor efficacy, this was due to better accumulation of mPEG-PLA in tumor cell via enhanced permeability and retention (EPR) effect. Therefore, DPT-PM has great clinical value, and can be expected to be a novel antitumor preparation.

Dual targeting curcumin loaded alendronate-hyaluronan- octadecanoic acid micelles for improving osteosarcoma therapy.

INTRODUCTION: Curcumin (CUR) is a general ingredient of traditional Chinese medicine, which has potential antitumor effects. However, its use clinically has been limited due to its low aqueous solubility and bioavailability. In order to improve the therapeutic effect of CUR on osteosarcoma (i.e., bone cancer), a multifunctional micelle was developed here by combining active bone accumulating ability with tumor CD44 targeting capacity. METHODS: The CUR loaded micelles were self-assembled by using alendronate-hyaluronic acid-octadecanoic acid (ALN-HA-C18) as an amphiphilic material. The obtained micelles were characterized for size and drug loading. In addition, the in vitro release behavior of CUR was investigated under PBS (pH 5.7) medium containing 1% Tween 80 at 37℃. Furthermore, an hydroxyapatite (the major inorganic component of bone) affinity experiment was studied. In vitro antitumor activity was evaluated. Finally, the anti-tumor efficiency was studied. RESULTS: The size and drug loading of the CUR loaded ALN-HA-C18 micelles were about 118 ± 3.6 nm and 6 ± 1.2%, respectively. CUR was released from the ALN-HA-C18 micelles in a sustained manner after 12 h. The hydroxyapatite affinity experiment indicated that CUR loaded ALN-HA-C18 micelles exhibited a high affinity to bone. CUR loaded ALN-HA-C18 micelles exhibited much higher cytotoxic activity against MG-63 cells compared to free CUR. Finally, CUR loaded ALN-HA-C18 micelles effectively delayed anti-tumor growth properties in osteosarcoma bearing mice as compared with free CUR. CONCLUSION: The present study suggested that ALN-HA-C18 is a novel promising micelle for osteosarcoma targeting and delivery of the hydrophobic anticancer drug CUR.

Stability, safety, and transcorneal mechanistic studies of ophthalmic lyophilized cyclosporine-loaded polymeric micelles.

INTRODUCTION: Cyclosporine-A (CsA) is generally used as an immunosuppressant and is also prescribed for some ophthalmic applications such as vernal keratoconjunctivitis and dry eye. However, it is limited clinically due to its low aqueous solubility and ocular bioavailability. METHODS: In this work, lyophilized methoxy poly(ethylene glycol)-poly(lactide) (mPEG-PLA) polymer micelles were prepared for ophthalmic formulations as a promising nanocarrier for hydrophobic drugs like CsA. A mPEG-PLA diblock polymer was synthesized by ring opening polymerization and CsA was loaded into mPEG-PLA micelles by a simple film dispersion method. A uniform design of experiments was utilized to optimize the final formulation. The obtained formulation was characterized for diameter (57.0±3.2 nm), entrapment efficiency % (98.51±1.4), and in vitro release. Moreover, incorporating the stabilizer mPEG2000 could increase the in vitro stability of the lyophilized CsA-loaded mPEG-PLA micelles. RESULTS: Results showed a sustained release of CsA from the micelles. Drug concentration and time-dependent cytotoxicity of human corneal epithelial-2 cells was observed. Additionally, the transcorneal mechanism of mPEG-PLA micelles was studied and the results showed that the mPEG-PLA micelles mainly absorbed by a paracellular pathway via corneal epithelial cells. CONCLUSION: Taken together, the results proved that this mPEG-PLA diblock polymer can be potentially used as a nanoscopic carrier to deliver hydrophobic drugs in a controlled manner to the ocular region and, thus, deserves further attention.

Optimization and characterization of deoxypodophyllotoxin loaded mPEG-PDLLA micelles by central composite design with response surface methodology.

The therapeutic application of deoxypodophyllotoxin (DPT) is limited due to its poor water solubility and stability. In the present study, the micelles assembled by the amphiphilic block copolymers (mPEG-PDLLA) were constructed to improve the solubility and safety of DPT for their in vitro and in vivo application. The central composite design was utilized to develop the optimal formulation composed of 1221.41 mg mPEG-PDLLA, the weight ratio of 1 : 4 (mPEG-PDLLA : DPT), 30 mL hydration volume and the hydration temperature at 40 °C. The results showed that the micelles exhibited uniformly spherical shape with the diameter of 20 nm. The drug-loading and entrapment efficiency of deoxypodophyllotoxin-polymeric micelles (DPT-PM) were about (20 ± 2.84)% and (98 ± 0.79)%, respectively, indicating that the mathematical models predicted well for the results. Compared to the free DPT, the cytotoxicity showed that blank micelles possessed great safety for Hela cells. In addition, the DPT loaded micelle formulation achieved stronger cytotoxicity at the concentration of 1 × 10-7 mol·L-1, which showed significant difference from free DPT (P < 0.05). In conclusion, the micelles were highly promising nano-carriers for the anti-tumor therapy with DPT.

Acid-sensitive hybrid polymeric micelles containing a reversibly activatable cell-penetrating peptide for tumor-specific cytoplasm targeting.

Cell-penetrating peptides (CPPs) have become a novel drug delivery system due to their distinct advantages, including high cell transmembrane potency and ability to carry cargo molecules inside cells. However, owing to their cationic charge and non-specificity characteristics, the clinical application of CPPs is limited. In the current study, we engineered a reversibly activatable cell-penetrating peptide (RACPP), containing oligoarginine fused to a pH-sensitive masking sequence via a polyglycine linker ((HE)10G5R6 or HE-CPP) with ultra-pH-sensitivity. The HE-CPP sequence was coupled to the surface of polyethyleneglycol-polylactic acid (PEG-PLA) polymer micelles (PMs-HE-CPP) to realize improve specificity and targeted delivery of encapsulated paclitaxel (PTX). PTX/PMs-HE-CPP showed the satisfactory encapsulated efficiency, loading capacity, size distribution as well as reversible charge-conversion in response to the surrounding pH. The zeta potential of PMs-HE-CPP was negative at pH 7.5, moderately positive at pH 6.5, and even more positive at a lower pH. Coumarin 6-loaded PMs-HE-CPP (C6/PMs-HE-CPP) showed enhanced tumor cellular uptake at a mildly acidic tumor microenvironment (pH 6.5) via energy-dependent and clathrin-mediated endocytosis. Furthermore, PTX/PMs-HE-CPP had significantly higher cytotoxicity toward mice breast cancer (4T1) cells at pH 6.5 versus at pH 7.4. In vivo imaging studies in 4T1-BALB/c tumor xenograft models confirmed the tumor-targeting characteristic of PMs-HE-CPP. PTX/PMs-HE-CPP also exhibited improved anti-tumor efficacy against unmodified polymer micelles and Taxol® in this tumor model. Accordingly, not only do RACPPs show the great potential to endow CPPs with specificity and reversible net-charge converting characteristic, they are also able to improve the targeting effect of nanoparticles.

Cisplatin-stitched α-poly(glutamatic acid) nanoconjugate for enhanced safety and effective tumor inhibition.

Conjugation of cisplatin to macromolecular carriers has been extensively studied for reducing systemic side effects. Here, a cisplatin-stitched α-poly(glutamatic acid) nanoconjugate with reduced adverse reactions and effective anti-tumor efficacy was synthesized via ionic interaction between platinum ion of cisplatin with carboxylic groups of α-poly(glutamatic acid). The nanoconjugate exhibited good water solubility, suitable size and polydispersity, almost spherical morphologies, and a sustained release profile without burst release. In vitro cytotoxicity and cell apoptosis assays performed in MCF-7 cells showed significantly decreased cytotoxicity of nanoconjugate compared with free cisplatin, and larger ratio of early apoptosis than late apoptosis. Quantitative cellular uptake assay also supported that conjugation of cisplatin to α-poly(glutamatic acid) reduced its cytotoxicity. Further studies revealed that the unique space structure of nanoconjugate acted as a shield for cisplatin against GSH detoxification under physiological conditions. In vivo studies regarding maximum tolerated dose, hematological parameters evaluation and histopathology assay demonstrated the superior safety of nanoconjugates. Furthermore, the nanoconjugates also achieved comparable antitumor efficacy with no apparent weight loss and death at a high equivalent cisplatin dose of 25 mg/kg. Moreover, the survival rate of mice treated with nanoconjugate was greatly larger than that of free cisplatin. These findings suggest that the cisplatin-stitched α-poly(glutamatic acid) nanoconjugate may hold great potential in clinical application for cancer therapy.

Improving the topical ocular pharmacokinetics of lyophilized cyclosporine A-loaded micelles: formulation, in vitro and in vivo studies.

Dry eye syndrome (DES) is one of the most common disorders of the eye for which combined treatment includes modification of the ocular environment and pathogenic therapies. Cyclosporine A (CsA), a immunosuppressive agent, has been demonstrated to be effective for the treatment of DES but is limited clinically by its low ocular bioavailability due to poor water solubility. In this paper, methoxy poly (ethylene glycol)-poly (lactide) polymer (mPEG-PLA) micelles were investigated as alternative vehicles for the solubilization and delivery of CsA to the eye. The in vitro stability indicated that CsA-loaded micellar lyophilized powder was stable for at least 3 months and the release profile showed a sustained release manner of CsA from micelles physically. In vivo ocular distribution studies demonstrated that the micellar formulations exhibited a 4.5-fold increase in retention effect at eyes compared with 0.05% CsA emulsion. In addition, the in vivo pharmacokinetics profile showed that the CsA-loaded micelles could enhance the retention time, achieving longer effect toward the DES. These studies proposed an effective micelle formulation as a novel ocular drug delivery system to improve solubility and bioavailability of ophthalmic CsA-controlled delivery.

Precisely Defined Polymers for Efficient Gene Delivery.

Gene therapy requires successful delivery of therapeutic nucleic acids into target cells; thus, efficient and safe gene delivery carriers are crucial to its success. Although many polymeric materials have shown their potential as effective nucleic acid carriers, the inherent heterogeneity and polydispersity of these polymers hinder their application in clinical studies because of difficulties in their further precise modification, structure-activity relationship study, as well as consistent manufacturing. Therefore, precisely defined polymers, with potential for site-specific optimization according to structure-activity relationship information and highly controllable production, have been extensively investigated. In this review, we focus on the design and development of precisely defined polymers for efficient gene delivery, illustrated with examples including dendrimers, peptide-based polymers, and sequence-defined oligoaminoamide oligomers.