Synthesis and biological evaluation of folic acid-rotenol conjugate as a potent targeted anticancer prodrug

Rotenone, a plant-based agricultural insecticide, has been shown to have anti-tumor activity through targeting mitochondrial complex I in cancer cells. However, off-target toxic side effect on nervous systems have greatly restricted the application of rotenone as anticancer drugs. Here, a folic acid-rotenol (FA-rotenol) conjugate was prepared by covalent coupling of the tumor-targeting ligand folic acid with rotenone derivative-rotenol to enhance its accumulation at tumor site. FA-rotenol conjugates present high in vitro cytotoxicties against several cell lines by inducing mitochondrial membrane potential depolarization and increasing the level of intracellular reactive oxygen species (ROS) to activate the mitochondrial pathway of apoptosis and enhance the G2/M cell cycle arrest. Because of the high affinity with over-expressed folate receptors, FA-rotenol conjugate demonstrated more effective in vivo therapeutic outcomes in 4T1 tumor-bearing mice than rotenone and rotenol. In addition, FA-rotenol conjugate can markedly inhibit the cell migration and invasion of HepG-2 cells. These studies confirm the feasibility of tumor-targeted ligand conjugated rotenone derivatives for targeted antitumor therapy; likewise, they lay the foundations for the development of other rotenol-conjugates with antitumor potential.

Discovery of novel tumor-targeted near-infrared probes with 6-substituted pyrrolo[2,3-d]pyrimidines as targeting ligands

Since the overexpression of folate receptors (FRs) in certain types of cancers, a variety of FR-targeted fluorescent probes for tumor detection have been developed. However, the reported probes almost all have the same targeting ligand of folic acid with various fluorophores and/or linkers. In the present study, a series of novel tumor-targeted near-infrared (NIR) molecular fluorescent probes were designed and synthesized based on previously reported 6-substituted pyrrolo[2,3-d]pyrimidine antifolates. All newly synthesized probes showed specific FR binding in vitro, whereas GT-NIR-4 and GT-NIR-5 with a benzene and a thiophene ring, respectively, on the side chain of pyrrolo[2,3-d]pyrimidine exhibited better FR binding affinity than that of GT-NIR-6 with folic acid as targeting ligand. GT-NIR-4 also showed high tumor uptake in KB tumor-bearing mice with good pharmacokinetic properties and biological safety. This work demonstrates the first attempt to replace folic acid with antifolates as targeting ligands for tumor-targeted NIR probes.

Customized multi-stimuli nanovehicles with dissociable 'bomblets' for photothermal-enhanced synergetic tumor therapy

Recently, the therapeutic effect of chemotherapy has been obviously impaired due to premature drug release, low tumor penetration, and multidrug resistance of nanoplatforms. In this paper, a novel multiple-sensitive drug delivery system (MC-ss-CDs) was developed by gating long-wavelength emitting carbon dots (CDs) on the openings of mesoporous carbon nanoparticles (MC) through disulfide bonds. The MC with excellent photothermal transition efficiency and high drug storage capacity for doxorubicin (DOX) was used as the delivery carrier. The CDs had multiple functions, including intelligent switching to hinder unwanted release, photothermal therapy (PTT) agents to improve the heat generation effect of MCs and bioimaging trackers to monitor drug delivery. The disulfide bonds, as the linkers between MC carriers and CDs, are stable under normal physical conditions and relatively labile under high GSH concentrations in the cytoplasm of tumor cells. After arriving at the tumor microenvironment, DOX/MC-ss-CDs can rapidly break into DOX/MC and CDs under high GSH concentrations. DOX/MC could realize efficient integration of PTT and chemotherapy on the surface of the tumor by stimuli-responsive DOX release and synergetic heating of MC and CDs. The small-sized CDs with excellent penetrating ability could effectively enter the deep tumor and realize NIR-triggered photothermal ablation. The DOX/MC-ss-CDs showed a chemophotothermal effect with a combination index of 0.38 in vitro and in vivo. Therefore, the DOX/MC-ss-CDs could be employed as a trackable nanovehicle for synergistic chemotherapy and PTT at different depths.

Multi-functional carboxymethyl chitin-based nanoparticles for modulation of tumor-associated macrophage polarity

Current challenge of using cytokines is its poor distribution and systemic side effects. To avoid this issue, we prepared the tumor-targeted and microenvironment-responsive nanocarriers (TRN), which were consisted of α-tocopheryl succinate (α-TOS) loaded mesoporous silica nanoparticles as cores, and surface-modified by thioketal-linkage, electrostatically coated with carboxymethyl chitin, and further anchored glucose-regulated protein 78-binding peptide as shells for encapsulating IL-12. TRN showed a size of 260 nm after encapsulated IL-12 and α-TOS with loading content of 0.0206% and 7.21%, respectively, and exhibited good biocompatibility to 4 T1 cells and macrophages. Moreover, IL-12/α-TOS loaded TRN displayed obvious anti-tumor efficacy on BALB/c nude mice bearing 4 T1 tumors, which was derived from promoted targeting to tumor tissue, endocytosed by macrophages and locally release IL-12 to subsequently repolarize tumor-associated macrophages into tumoricidal M1 phenotype with reduced side effects. The nanosystem exhibited as a promising strategy with functional conversion of macrophages in tumor microenvironment for anti-tumor therapy.

Multi-stimuli responsive nanosystem modified by tumor-targeted carbon dots for chemophototherapy synergistic therapy

In this work, a tumor-targeted and multi-stimuli responsive drug delivery system combining infrared thermal imaging of cells with thermo-chemotherapy was developed. Oxidized mesoporous carbon nanoparticles (MCNs-COOH) with high photothermal conversion ability (photothermal transduction efficiency η = 27.4%) in near-infrared (NIR) region were utilized to encapsulate doxorubicin (DOX). The outer surfaces of MCNs-COOH were capped with multifunctional carbon dots (CD_HA) as simultaneous smart gatekeepers, a tumor targeting moiety and a fluorescent probe. NIR laser irradiation killed cancer cells through NIR-light induced hyperthermia, facilitated chemotherapeutic drug release and enhanced the sensitivity of tumor cells to drugs. The therapeutic efficacy in two-dimensional (2D) and three-dimensional (3D) cells demonstrated that MC-CD_HA loading DOX (MC-CD_HA/DOX) had good chemo-photothermal synergistic antitumor effects (combination index of CI = 0.448). The biodistribution and pharmacodynamics experiments of MC-CD_HA/DOX in the 4T1 tumor model indicated that MCNs-COOH prolonged the residence time of DOX in tumor tissues and therefore actualized effective synergistic photothermal chemotherapy. By combining these excellent capabilities, the tumor-targeted and multi-stimuli responsive drug delivery system can be utilized as a visible nanoplatform for chemophotothermal synergistic therapy.

Copper sulfide nanoparticle-based localized drug delivery system as an effective cancer synergistic treatment and theranostic platform

Localized cancer treatment with combination therapy has attracted increasing attention for effective inhibition of tumor growth. In this work, we introduced diffusion molecular retention (DMR) tumor targeting effect, a new strategy that employed transferrin (Tf) modified hollow mesoporous CuS nanoparticles (HMCuS NPs) to undergo extensive diffuse through the interstitium and tumor retention after a peritumoral (PT) injection. Herein, HMCuS NPs with strong near-infrared (NIR) absorption and photothermal conversion efficiency could serve as not only a drug carrier but also a powerful contrast agent for photoacoustic imaging to guide chemo-phototherapy. The iron-dependent artesunate (AS), which possessed profound cytotoxicity against tumor cell, was used as model drug. As a result, this AS loaded Tf-HMCuS NPs (AS/Tf-HMCuS NPs) system could specially target to tumor cells and synchronously deliver AS as well as irons into tumor to achieve enhanced antitumor activity. It was found that AS/Tf-HMCuS NPs was taken up by MCF-7 cells via Tf-mediated endocytosis, and could effectively convert NIR light into heat for photothermal therapy as well as generated high levels of reactive oxygen species (ROS) for photodynamic therapy. In addition, in vivo antitumor efficacy studies showed that tumor-bearing mice treated with AS/Tf-HMCuS NPs through peritumoral (PT) injection under NIR laser irradiation displayed the strongest inhibition rate of about 74.8%, even with the reduced frequency of administration. Furthermore, to demonstrate DMR, the optical imaging, photoacoustic tomography and immunofluorescence after PT injection were adopted to track the behavior of AS/Tf-HMCuS NPs in vivo. The results exhibited that Tf-HMCuS NPs prolonged the local accumulation and retention together with slow vascular uptake and extensive interstitial diffusion, which was consistent with the biodistribution studies of AS/Tf-HMCuS NPs. Therefore, the approach of localized delivery through DMR combined with multi-mechanism therapy may be a promising method for cancer treatment.

STATEMENT OF SIGNIFICANCE

In recent years, localized cancer treatment using different biomaterials has attracted increasing attention for effective inhibition of tumor growth. However, it is still challenging for this kind of system to achieve a high drug loading, overcome biological barriers from the site of injection to the site of action, and combine synergetic therapy with diagnosis without adversely affecting the formation process. This study provides a localized diffusion molecular retention (DMR) tumor targeting drug delivery system based on hollow mesoporous copper sulfide nanoparticles (HMCuS NPs) entrapment of anticancer drug for the first time, which can achieve high drug loading, improve local drug accumulation and retention, accomplish synergistic combination of chemo-phototherapy, and finally enhance antitumor effect. In addition, HMCuS NPs also possesses the property suitable for photoacoustic imaging, which could offer us a theranostic platform.

Redox-responsive mesoporous selenium delivery of doxorubicin targets MCF-7 cells and synergistically enhances its anti-tumor activity

To reduce the side effects and enhance the anti-tumor activities of anticancer drugs in the clinic, the use of nano mesoporous materials, with mesoporous silica (MSN) being the best-studied, has become an effective method of drug delivery. In this study, we successfully synthesized mesoporous selenium (MSe) nanoparticles and first introduced them to the field of drug delivery. Loading MSe with doxorubicin (DOX) is mainly driven by the physical adsorption mechanism of the mesopores, and our results demonstrated that MSe could synergistically enhance the antitumor activity of DOX. Coating the surface of MSe@DOX with Human serum albumin (HSA) generated a unique redox-responsive nanoparticle (HSA-MSe@DOX) that demonstrated glutathione-dependent drug release, increased tumor-targeting effects and enhanced cellular uptake throug nanoparticle interact with SPARC in MCF-7 cells. In vitro, HSA-MSe@DOX prominently induced cancer cell toxicity by synergistically enhancing the effects of MSe and DOX. Moreover, HSA-MSe@DOX possessed tumor-targeting abilities in tumor-bearing nude mice and not only decreased the side effects associated with DOX, but also enhanced its antitumor activity. Therefore, HSA-MSe@DOX is a promising new drug that warrants further evaluation in the treatments of tumors.

STATEMENT OF SIGNIFICANCE

To reduce the side effects and enhance the anti-tumor activities of anticancer drugs, we successfully synthesized mesoporous selenium (MSe) nanoparticles and first introduced them to the field of drug delivery. Loading MSe with doxorubicin (DOX) is mainly driven by the physical adsorption mechanism of the mesopores. Coating the surface of MSe@DOX with Human serum albumin (HSA) generated a unique redox-responsive nanoparticle (HSA-MSe@DOX) that demonstrated glutathione-dependent drug release, increased tumor-targeting effects and enhanced cellular uptake throug nanoparticle interact with SPARC in MCF-7 cells. In vitro and in vivo, HSA-MSe@DOX possessed tumor-targeting abilities and not only decreased the side effects associated with DOX, but also enhanced its antitumor activity. Therefore, HSA-MSe@DOX is a promising new drug that warrants further evaluation in the treatments of tumors.

Tumor-targeted pH/redox dual-sensitive unimolecular nanoparticles for efficient siRNA delivery

A unique pH/redox dual-sensitive cationic unimolecular nanoparticle (NP) enabling excellent endosomal/lysosomal escape and efficient siRNA decomplexation inside the target cells was developed for tumor-targeted delivery of siRNA. siRNA was complexed into the cationic core of the unimolecular NP through electrostatic interactions. The cationic core used for complexing siRNA contained reducible disulfide bonds that underwent intracellular reduction owing to the presence of high concentrations of reduced glutathione (GSH) inside the cells, thereby facilitating the decomplexation of siRNA from the unimolecular NPs. The cationic polymers were conjugated onto the hyperbranched core (H40) via a pH-sensitive bond, which further facilitated the decomplexation of siRNA from the NPs. In vitro studies on the siRNA release behaviors showed that dual stimuli (pH=5.3, 10mM GSH) induced the quickest release of siRNA from the NPs. In addition, the imidazole groups attached to the cationic polymer segments enhanced the endosomal/lysosomal escape of NPs via the proton sponge effect. Intracellular tracking studies revealed that siRNA delivered by unimolecular NPs was efficiently released to the cytosol. Moreover, the GE11 peptide, an anti-EGFR peptide, enhanced the cellular uptake of NPs in MDA-MB-468, an EFGR-overexpressing triple negative breast cancer (TNBC) cell line. The GE11-conjugated, GFP-siRNA-complexed NPs exhibited excellent GFP gene silencing efficiency in GFP-MDA-MB-468 TNBC cells without any significant cytotoxicity. Therefore, these studies suggest that this smart unimolecular NP could be a promising nanoplatform for targeted siRNA delivery to EFGR-overexpressing cancer cells.

Tumor-targeted and multi-stimuli responsive drug delivery system for near-infrared light induced chemo-phototherapy and photoacoustic tomography

In this work, a tumor-targeted and multi-stimuli responsive drug delivery system has been developed for combining photoacoustic tomography imaging with chemo-phototherapy. We utilized a kind of near infrared (NIR) resonant material-hollow mesoporous copper sulfide nanoparticles (HMCuS NPs) to encapsulate doxorubicin (DOX). After that, the outer surface of HMCuS NPs was capped with multifunctional hyaluronic acid (HA) simultaneously as smart gatekeeper as well as tumor targeting moiety. Herein, HMCuS-HA could serve as a powerful contrast agent for photoacoustic tomography (PAT) to guide chemo-phototherapy by providing the identification of cancerous lesions. In vitro and in vivo studies, the nanoplatform (DOX/HMCuS-HA) pinpointed MCF-7 cells via CD44 receptor-mediated endocytosis pathway. Subsequently, intracellular enzyme-responsive controlled drug release would take place in lysosome after the HA degradation by hyaluronidase. Under near infrared (NIR) light irradiation, HMCuS NPs could not only effectively convert NIR light into heat for photothermal therapy, but also generate high levels of reactive oxygen species (ROS) for photodynamic therapy. In addition, NIR light and low pH environment could facilitate intracellular tunable drug release with spatial/temporal resolution, and thus synergistic combination of chemo-phototherapy should be simultaneously driven by an 808nm laser irradiation, which brought out an outstanding therapeutic effect. In vivo optical imaging demonstrated that HMCuS-HA significantly enhanced targeting and accumulation capacity in tumor site. Furthermore, tumor-bearing mice treated with DOX/HMCuS-HA under NIR irradiation (808nm, 2W/cm(2), 0.5min) in vivo displayed the highest inhibition ratio of about 88.9%. Taken together, our present study of the tumor-targeted and multi-stimuli responsive drug delivery system provides new insights into multimodality theranostic applications in cancer treatment.

STATEMENT OF SIGNIFICANCE

Until now, chemotherapy is still the major therapeutic approach applied in oncology. Despite their pharmacologically efficacy in cancer treatments, most chemotherapeutic agents without tumor-specific targeting ability have brought out serious toxicities to normal tissues. This study provides a promising near infrared (NIR) resonant material-hollow mesoporous copper sulfide nanoparticles (HMCuS NPs) with capping of multifunctional hyaluronic acid (HA) simultaneously as smart gatekeeper as well as tumor targeting moiety to address the above problem. After the nanoplatform (DOX/HMCuS-HA) pinpointed breast cancer cells via CD44 receptor-mediated endocytosis pathway, intracellular multi-stimuli responsive controlled drug release would take place with remarkable spatial/temporal resolution. Then photoacoustic tomography (PAT) and synergistic combination of chemo-phototherapy would be simultaneously driven by the same NIR irradiation in a coordinated way, which brought out an outstanding theranostic effect. This work can arouse broad interests among researchers in the fields of nanomedicine, nanotechnology, and drug delivery system.

A self-assembled system for tumor-targeted co-delivery of drug and gene

A new cationic polymer eprosartan-graft-PEI (ESP) containing eprosartan (ES) and polyethylenimine 1.8K was successfully developed and employed as a safe gene vector to assemble a drug (ES) and gene co-delivery complex (ESP/pDNA). Chondroitin sulfate (CS) was then used as a coating polymer to shield the surface charge of ESP/pDNA complexes, as well as a tumor targeting entity to ensure specific delivery of CS/ESP/pDNA complexes. The CS/ESP/pDNA complexes with desirable particle size and zeta potential, exhibited amidase-responsive drug release and CS-mediated endocytosis in vitro. As compared with ESP/pDNA complexes, in vivo imaging results demonstrated decreased reticuloendothelial system uptake and remarkably increased tumor accumulation of CS/ESP/pDNA complexes. All these findings indicated the potential of CS/ESP/pDNA as a promising tumor-targeted drug and gene co-delivery system.

Design, synthesis and biological evaluation of a highly-potent and cancer cell selective folate-taxoid conjugate

The folate receptor (FR) has been widely recognized as an excellent target for the tumor-selective delivery of cytotoxic agents, and four folate-drug conjugates have entered clinical evaluations for the treatment of solid tumors to date. However, most of these conjugates required structural modification of the cytotoxic warheads in order to achieve efficient drug release from the linkers. We designed and constructed a novel folate conjugate of a highly-potent next-generation taxoid, SB-T-1214, by exploiting bioorthogonal Cu-free 'click' chemistry. The synthesis was highly convergent and required no HPLC purification to obtain the final folate-taxoid conjugate 1. Conjugate 1 demonstrated highly FR-specific potency (IC₅₀ 2.1-3.5 nM) against a panel of cancer cell lines, with a >1000-fold decrease in cytotoxicity against normal human cells (IC₅₀>5000 nM). The remarkable potency and selectivity of conjugate 1 can be attributed to highly FR-specific receptor-mediated endocytosis as well as efficient release of the unmodified cytotoxic warhead using a mechanism-based self-immolative linker.

Fluorine-Containing Taxoid Anticancer Agents and Their Tumor-Targeted Drug Delivery

A long-standing problem of conventional chemotherapy is the lack of tumor-specific treatments. Traditional chemotherapy relies on the premise that rapidly proliferating cancer cells are more likely to be killed by a cytotoxic agent. In reality, however, cytotoxic agents have very little or no specificity, which leads to systemic toxicity, causing undesirable severe side effects. Consequently, various "molecularly targeted cancer therapies" have been developed for use in specific cancers, including tumor-targeting drug delivery systems. In general, such a drug delivery system consists of a tumor recognition moiety and a cytotoxic "warhead" connected through a "smart" linker to form a conjugate. When a multi-functionalized nanomaterial is used as the vehicle, a "Trojan Horse" approach can be used for mass delivery of cytotoxic "warheads" to maximize the efficacy. Exploitation of the special properties of fluorine has proven successful in the development of new and effective biochemical tools as well as therapeutic agents. Fluorinated congeners can also serve as excellent probes for the investigation of biochemical mechanisms. ¹⁹F-NMR can provide unique and powerful tools for mechanistic investigations in chemical biology. This account presents our recent progress, in perspective, on the molecular approaches to the design and development of novel tumor-targeted drug delivery systems for new generation chemotherapy by exploiting the unique nature of fluorine.