Safe and Effective Reversal of Cancer Multidrug Resistance Using Sericin‐Coated Mesoporous Silica Nanoparticles for Lysosome‐Targeting Delivery in Mice

Multidrug resistance (MDR) and adverse side effects are the major challenges facing cancer chemotherapy. Here, pH/protease dually responsive, sericin‐coated mesoporous silica nanoparticles (SMSNs) for lysosomal delivery of doxorubicin (DOX) to overcome MDR and reduce systemic toxicity are reported. Sericin, a natural protein from silkworm cocoons, is coated onto MSNs as a gatekeeper via pH sensitive imine linkages. The sericin shell prevents the premature leakage of encapsulated DOX from MSNs in extracellular environment. Once reaching drug‐resistant tumors, sericin's cell‐adhesive bioactivity enhances cellular uptake of SMSNs that are in turn transported into perinuclear lysosomes, thus avoiding drug efflux mediated by membrane‐bound pumps. Lysosomal acidity triggers cleavage of pH sensitive linkage between sericin and MSNs concurrently with lysosomal proteases deconstructing sericin shell. This pH/protease dual responsiveness leads to DOX burst release into cell nuclei, inducing effective cell death, thus reversing MDR. These DOX‐loaded SMSNs not only effectively kill drug‐resistant cells in vitro, but also significantly reduce the growth of DOX‐resistant MCF‐7/ADR (breast cancer cells) tumor by 70% in a preclinical animal model without eliciting systemic toxicity frequently encountered in current clinical therapeutic formulations. Thus, the dually responsive SMSNs are an effective, lysosome‐tropic, and bio‐safe delivery system for chemotherapeutics for combating MDR.     

pH‐ and NIR Light‐Responsive Polymeric Prodrug Micelles for Hyperthermia‐Assisted Site‐Specific Chemotherapy to Reverse Drug Resistance in Cancer Treatment

Despite the exciting advances in cancer chemotherapy over past decades, drug resistance in cancer treatment remains one of the primary reasons for therapeutic failure. IR‐780 loaded pH‐responsive polymeric prodrug micelles with near infrared (NIR) photothermal effect are developed to circumvent the drug resistance in cancer treatment. The polymeric prodrug micelles are stable in physiological environment, while exhibit fast doxorubicin (DOX) release in acidic condition and significant temperature elevation under NIR laser irradiation. Phosphorylcholine‐based biomimetic micellar shell and acid‐sensitive drug conjugation endow them with prolonged circulation time and reduced premature drug release during circulation to conduct tumor site‐specific chemotherapy. The polymeric prodrug micelles combined with NIR laser irradiation could significantly enhance intracellular DOX accumulation and synergistically induce the cell apoptosis in DOX‐resistant MCF‐7/ADR cells. Meanwhile, the tumor site‐specific chemotherapy combined with hyperthermia effect induces significant inhibition of MCF‐7/ADR tumor growth in tumor‐bearing mice. These results demonstrate that the well‐designed IR‐780 loaded polymeric prodrug micelles for hyperthermia‐assisted site‐specific chemotherapy present an effective approach to reverse drug resistance.     

An Ultra pH‐Sensitive and Aptamer‐Equipped Nanoscale Drug‐Delivery System for Selective Killing of Tumor Cells

Nanotechnology has often been applied in the development of targeted drug‐delivery systems for the treatment of cancer. An ideal nanoscale system for drug delivery should be able to selectively deliver and rapidly release the carried therapeutic drug(s) in cancer cells and, more importantly, not react to off‐target cells so as to eliminate unwanted toxicity on normal tissues. To reach this goal, a selective chemotherapeutic is formulated using a hollow gold nanosphere (HAuNS) equipped with a biomarker‐specific aptamer (Apt), and loaded with the chemotherapy drug doxorubicin (DOX). The formed Apt‐HAuNS‐Dox, approximately 42 nm in diameter, specifically binds to lymphoma tumor cells and does not react to control cells that do not express the biomarker. Through aptamer‐mediated selective cell binding, the Apt‐HAuNS‐Dox is internalized exclusively into the targeted tumor cells, and then released the DOX intracellularly. Of note, although the formed Apt‐HAuNS‐Dox is stable under normal biological conditions (pH 7.4), it appears ultrasensitive to pH change and rapidly releases 80% of the loaded DOX within 2 h at pH 5.0, a condition seen in cell lysosomes. Functional assays using cell mixtures show that the Apt‐HAuNS‐Dox selectively kills lymphoma tumor cells, but has no effect on the growth of the off‐target cells in the same cultures, indicating that this ultra pH‐sensitive Apt‐HAuNS‐Dox can selectively treat cancer through specific aptamer guidance, and will have minimal side effects on normal tissue.     

pH‐Responsive PEG‐Shedding and Targeting Peptide‐Modified Nanoparticles for Dual‐Delivery of Irinotecan and microRNA to Enhance Tumor‐Specific Therapy

Irinotecan is one of the main chemotherapeutic agents for colorectal cancer (CRC). MicroRNA‐200 (miR‐200) has been reported to inhibit metastasis in cancer cells. Herein, pH‐sensitive and peptide‐modified liposomes and solid lipid nanoparticles (SLN) are designed for encapsulation of irinotecan and miR‐200, respectively. These peptides include one cell‐penetrating peptide, one ligand targeted to tumor neovasculature undergoing angiogenesis, and one mitochondria‐targeting peptide. The peptide‐modified nanoparticles are further coated with a pH‐sensitive PEG‐lipid derivative with an imine bond. These specially‐designed nanoparticles exhibit pH‐responsive release, internalization, and intracellular distribution in acidic pH of colon cancer HCT116 cells. These nanoparticles display low toxicity to blood and noncancerous intestinal cells. Delivery of miR‐200 by SLN further increases the cytotoxicity of irinotecan‐loaded liposomes against CRC cells by triggering apoptosis and suppressing RAS/β‐catenin/ZEB/multiple drug resistance (MDR) pathways. Using CRC‐bearing mice, the in vivo results further indicate that irinotecan and miR‐200 in pH‐responsive targeting nanoparticles exhibit positive therapeutic outcomes by inhibiting colorectal tumor growth and reducing systemic toxicity. Overall, successful delivery of miR and chemotherapy by multifunctional nanoparticles may modulate β‐catenin/MDR/apoptosis/metastasis signaling pathways and induce programmed cancer cell death. Thus, these pH‐responsive targeting nanoparticles may provide a potential regimen for effective treatment of colorectal cancer.     

Inhibition of 3‐D Tumor Spheroids by Timed‐Released Hydrophilic and Hydrophobic Drugs from Multilayered Polymeric Microparticles

First‐line cancer chemotherapy necessitates high parenteral dosage and repeated dosing of a combination of drugs over a prolonged period. Current commercially available chemotherapeutic agents, such as Doxil and Taxol, are only capable of delivering single drug in a bolus dose. The aim of this study is to develop dual‐drug‐loaded, multilayered microparticles and to investigate their antitumor efficacy compared with single‐drug‐loaded particles. Results show hydrophilic doxorubicin HCl (DOX) and hydrophobic paclitaxel (PTX) localized in the poly(dl ‐lactic‐co‐glycolic acid, 50:50) (PLGA) shell and in the poly(l ‐lactic acid) (PLLA) core, respectively. The introduction of poly[(1,6‐bis‐carboxyphenoxy) hexane] (PCPH) into PLGA/PLLA microparticles causes PTX to be localized in the PLLA and PCPH mid‐layers, whereas DOX is found in both the PLGA shell and core. PLGA/PLLA/PCPH microparticles with denser shells allow better control of DOX release. A delayed release of PTX is observed with the addition of PCPH. Three‐dimensional MCF‐7 spheroid studies demonstrate that controlled co‐delivery of DOX and PTX from multilayered microparticles produces a greater reduction in spheroid growth rate compared with single‐drug‐loaded particles. This study provides mechanistic insights into how distinctive structure of multilayered microparticles can be designed to modulate the release profiles of anticancer drugs, and how co‐delivery can potentially provide better antitumor response.     

Holo‐Lactoferrin Modified Liposome for Relieving Tumor Hypoxia and Enhancing Radiochemotherapy of Cancer

Hypoxic microenvironments in the solid tumor play a negative role in radiotherapy. Holo‐lactoferrin (holo‐Lf) is a natural protein, which acts as a potential ligand of transferrin receptor (TfR). In this work, an anticancer drug, doxorubicin (Dox)‐loaded liposome‐holo‐Lf nanocomposites, is developed for tumor targeting and imaging guided combined radiochemotherapy. Dox‐loaded liposome‐holo‐Lf (Lf‐Liposome‐Dox) nanocomposites exhibit significant cellular uptake likely owing to the TfR receptor‐mediated targeting accumulation of Lf‐Liposome‐Dox nanocomposites. Additionally, the nanocomposites exhibit high accumulation in the tumor site after intravenous injection as evidenced from in vivo fluorescence imaging. More importantly, it is found that the holo‐Lf has the ability to catalyze the conversion of hydrogen peroxide (H₂O₂) to oxygen for relieving the tumor hypoxic microenvironment. Photoacoustic imaging further confirms the abundant generation of oxygen in the presence of Lf‐Liposome‐Dox nanocomposites. Based on these findings, in vivo combined radiochemotherapy is performed using Lf‐Liposome‐Dox as therapeutic agent, achieving excellent cancer treatment effect. The study further promotes the potential biomedical application of holo‐Lf in cancer treatment.     

Mixed Nanosized Polymeric Micelles as Promoter of Doxorubicin and miRNA‐34a Co‐Delivery Triggered by Dual Stimuli in Tumor Tissue

Dual stimuli‐sensitive mixed polymeric micelles (MM) are developed for co‐delivery of the endogenous tumor suppressor miRNA‐34a and the chemotherapeutic agent doxorubicin (Dox) into cancer cells. The novelty of the system resides in two stimuli‐sensitive prodrugs, a matrix metalloproteinase 2 (MMP2)‐sensitive Dox conjugate and a reducing agent (glutathione, GSH)‐sensitive miRNA‐34a conjugate, self‐assembled in a single particle decorated with a polyethylene glycol corona for longevity, and a cell‐penetrating peptide (TATp) for enhanced intracellular delivery. The MMP2‐sensitivity of the system results in threefold higher cytotoxicity in MMP2‐overexpressing HT1080 cells compared to low MMP2‐expressing MCF7 cells. Cellular internalization of Dox increases by more than 70% after inclusion of TATp to the formulation. MMP2‐sensitive MM also inhibits proliferation and migration of HT1080 cells. Moreover, GSH‐sensitive MM allows for an efficient downregulation of Bcl2, survivin, and notch1 (65%, 55%, and 46%, respectively) in HT1080 cells. Combination of both conjugates in dual sensitive MM reduces HT1080 cell viability to 40% and expression of Bcl2 and survivin. Finally, 50% cell death is observed in 3D models of tumor mass. The results confirm the potential of the MM to codeliver miRNA‐34a and doxorubicin triggered by dual stimuli inherent of tumor tissues.     

Cancer Cell Membrane Camouflaged Semi‐Yolk@Spiky‐Shell Nanomotor for Enhanced Cell Adhesion and Synergistic Therapy

Cell adhesion of nanosystems is significant for efficient cellular uptake and drug delivery in cancer therapy. Herein, a near‐infrared (NIR) light‐driven biomimetic nanomotor is reported to achieve the improved cell adhesion and cellular uptake for synergistic photothermal and chemotherapy of breast cancer. The nanomotor is composed of carbon@silica (C@SiO₂) with semi‐yolk@spiky‐shell structure, loaded with the anticancer drug doxorubicin (DOX) and camouflaged with MCF‐7 breast cancer cell membrane (i.e., mC@SiO₂@DOX). Such biomimetic mC@SiO₂@DOX nanomotors display efficient self‐thermophoretic propulsion due to a thermal gradient generated by asymmetrically spatial distribution. Moreover, the MCF‐7 cancer cell membrane coating can remarkably reduce the bioadhesion of nanomotors in biological medium and exhibit highly specific self‐recognition of the source cell line. The combination of effective propulsion and homologous targeting dramatically improves cell adhesion and the resultant cellular uptake efficiency in vitro from 26.2% to 67.5%. Therefore, the biomimetic mC@SiO₂@DOX displays excellent synergistic photothermal and chemotherapy with over 91% MCF‐7 cell growth inhibition rate. Such smart design of the fuel‐free, NIR light‐powered biomimetic nanomotor may pave the way for the application of self‐propelled nanomotors in biomedicine.     

Codelivery of Anti‐PD‐1 Antibody and Paclitaxel with Matrix Metalloproteinase and pH Dual‐Sensitive Micelles for Enhanced Tumor Chemoimmunotherapy

Immune checkpoint blockade (ICB) is demonstrating great potential in cancer immunotherapy nowadays. Yet, the low response rate to ICB remains an urgent challenge for tumor immunotherapy. A pH and matrix metalloproteinase dual‐sensitive micellar nanocarrier showing spatio‐temporally controlled release of anti‐PD‐1 antibody (aPD‐1) and paclitaxel (PTX) in solid tumors is prepared to realize synergistic cancer chemoimmunotherapy. Antitumor immunity can be activated by PTX‐induced immunogenic cell death (ICD), while aPD‐1 blocks the PD‐1/PD‐L1 axis to suppress the immune escape due to PTX‐induced PD‐L1 up‐regulation, thus resulting in a synergistic antitumor chemoimmunotherapy. Through decoration with a sheddable polyethylene glycol (PEG) shell, the nanodrug may better accumulate in tumors to boost the synergistic antitumor treatment in a mouse melanoma model. The present study demonstrates a potent antitumor chemoimmunotherapy utilizing tumor microenvironment‐sensitive micelles bearing a sheddable PEG layer to mediate site‐specific sequential release of aPD‐1 and PTX.     

Nanoparticle‐Enhanced Radiotherapy to Trigger Robust Cancer Immunotherapy

External radiotherapy is extensively used in clinic to destruct tumors by locally applied ionizing‐radiation beams. However, the efficacy of radiotherapy is usually limited by tumor hypoxia‐associated radiation resistance. Moreover, as a local treatment technique, radiotherapy can hardly control tumor metastases, the major cause of cancer death. Herein, core–shell nanoparticles based poly(lactic‐co‐glycolic) acid (PLGA) are fabricate, by encapsulating water‐soluble catalase (Cat), an enzyme that can decompose H₂O₂ to generate O₂, inside the inner core, and loading hydrophobic imiquimod (R837), a Toll‐like‐receptor‐7 agonist, within the PLGA shell. The formed PLGA‐R837@Cat nanoparticles can greatly enhance radiotherapy efficacy by relieving the tumor hypoxia and modulating the immune‐suppressive tumor microenvironment. The tumor‐associated antigens generated postradiotherapy‐induced immunogenic cell death in the presence of such R837‐loaded adjuvant nanoparticles will induce strong antitumor immune responses, which together with cytotoxic T‐lymphocyte associated protein 4 (CTLA‐4) checkpoint blockade will be able to effectively inhibit tumor metastases by a strong abscopal effect. Moreover, a long term immunological memory effect to protect mice from tumor rechallenging is observed post such treatment. This work thus presents a unique nanomedicine approach as a next‐generation radiotherapy strategy to enable synergistic whole‐body therapeutic responses after local treatment, greatly promising for clinical translation.     

Theranostic Upconversion Nanobeacons for Tumor mRNA Ratiometric Fluorescence Detection and Imaging‐Monitored Drug Delivery

Remote optical detection and imaging of specific tumor‐related biomarkers and simultaneous activation of therapy according to the expression level of the biomarkers in tumor site with theranostic probes should be an effective modality for treatment of cancers. Herein, an upconversion nanobeacon (UCNPs‐MB/Dox) is proposed as a new theranostic nanoprobe to ratiometrically detect and visualize the thymidine kinase 1 (TK1) mRNA that can simultaneously trigger the Dox release to activate the chemotherapy accordingly. UCNPs‐MB/Dox is constructed with the conjugation of a TK1 mRNA‐specific molecular beacon (MB) bearing a quencher (BHQ‐1) and an alkene handle modified upconversion nanoparticle (UCNP) through click reaction and subsequently loading with a chemotherapy drug (Dox). With this nanobeacon, quantitative ratiometric upconversion detection of the target with high sensitivity and selectivity as well as the target triggered Dox release in vitro is demonstrated. The sensitive and selective ratiometric detection and imaging of TK1 mRNA under the irradiation of near infrared light (980 nm) and the mRNA‐dependent release of Dox for chemotherapy in the tumor MCF‐7 cells and A549 cells are also shown. This work provides a smart and robust platform for gene‐related tumor theranostics.     

Emergence of Gold‐Mesoporous Silica Hybrid Nanotheranostics: Dox‐Encoded,Folate Targeted Chemotherapy with Modulation of SERS Fingerprinting for Apoptosis Toward Tumor Eradication

Strategically fabricated theranostic nanocarrier delivery system is an unmet need in personalized medicine. Herein, this study reports a versatile folate receptor (FR) targeted nanoenvelope delivery system (TNEDS) fabricated with gold core silica shell followed by chitosan–folic acid conjugate surface functionalization by for precise loading of doxorubicin (Dox), resembled as Au@SiO₂‐Dox‐CS‐FA. TNEDS possesses up to 90% Dox loading efficiency and internalized through endocytosis pathway leading to pH and redox‐sensitive release kinetics. The superior FR‐targeted cytotoxicity is evaluated by the nanocarrier in comparison with US Food and Drug Administration (FDA)‐approved liposomal Dox conjugate, Lipodox. Moreover, TNEDS exhibits theranostic features through caspase‐mediated apoptosis and envisages high surface plasmon resonance enabling the nanoconstruct as a promising surface enhanced Raman scattering (SERS) nanotag. Minuscule changes in the biochemical components inside cells exerted by the TNEDS along with the Dox release are evaluated explicitly in a time‐dependent fashion using bimodal SERS/fluorescence nanoprobe. Finally, TNEDS displays superior antitumor response in FR‐positive ascites as well as solid tumor syngraft mouse models. Therefore, this futuristic TNEDS is expected to be a potential alternative as a clinically relevant theranostic nanomedicine to effectively combat neoplasia.     

Conjugate of Doxorubicin to Albumin‐Binding Peptide Outperforms Aldoxorubicin

Short circulation time and off‐target toxicity are the main challenges faced by small‐molecule chemotherapeutics. To overcome these shortcomings, an albumin‐binding peptide conjugate of chemotherapeutics is developed that binds specifically to endogenous albumin and harnesses its favorable pharmacokinetics and pharmacodynamics for drug delivery to tumors. A protein‐G‐derived albumin‐binding domain (ABD) is conjugated with doxorubicin (Dox) via a pH‐sensitive linker. One to two Dox molecules are conjugated to ABD without loss of aqueous solubility. The albumin‐binding ABD–Dox conjugate exhibits nanomolar affinity for human and mouse albumin, and upon administration in mice, shows a plasma half‐life of 29.4 h, which is close to that of mouse albumin. Additionally, 2 h after administration, ABD–Dox exhibits an approximately 4‐fold higher concentration in the tumor than free Dox. Free Dox clears quickly from the tumor, while ABD–Dox maintains a steady concentration in the tumor for at least 72 h, so that its relative accumulation at 72 h is ≈120‐fold greater than that of free Dox. The improved pharmacokinetics and biodistribution of ABD–Dox result in enhanced therapeutic efficacy in syngeneic C26 colon carcinoma and MIA PaCa‐2 pancreatic tumor xenografts, compared with free Dox and aldoxorubicin, an albumin‐reactive Dox prodrug currently in clinical development.     

Sequentially Responsive Shell‐Stacked Nanoparticles for Deep Penetration into Solid Tumors

Nanomedicine to overcome both systemic and tumor tissue barriers ideally should have a transformable size and surface, maintaining a certain size and negative surface charge for prolonged circulation, while reducing to a smaller size and switching to a positive surface charge for efficient penetration to and retention in the interstitial space throughout the tumor tissue. However, the design of such size and charge dual‐transformable nanomedicine is rarely reported. Here, the design of a shell‐stacked nanoparticle (SNP) is reported, which can undergo remarkable size reduction from about 145 to 40 nm, and surface charge reversal from ?7.4 to 8.2 mV at acidic tumor tissue, for enhanced tumor penetration and uptake by cells in deep tumor tissue. The disulfide‐cross‐linked core maintains the stability of the particle and prevents undesired premature drug release until the shedding of the shell, which accelerates the cleavage of more exposed disulfide bond sand intracellular drug release. SNP penetrates about 1 mm into xenografted A549 lung carcinoma, which is about four times penetration depth of the nontransformable one. The doxorubicin (DOX)‐loaded SNP (SNP/DOX) shows significant antitumor efficacy and nearly eradicates the tumor, substantiating the importance of the design of size and charge dual‐transformable nanomedicine.     

A Surface‐Charge Study on Cellular‐Uptake Behavior of F3‐Peptide‐Conjugated Iron Oxide Nanoparticles

Surface‐charge measurements of mammalian cells in terms of Zeta potential are demonstrated as a useful biological characteristic in identifying cellular interactions with specific nanomaterials. A theoretical model of the changes in Zeta potential of cells after incubation with nanoparticles is established to predict the possible patterns of Zeta‐potential change to reveal the binding and internalization effects. The experimental results show a distinct pattern of Zeta‐potential change that allows the discrimination of human normal breast epithelial cells (MCF‐10A) from human cancer breast epithelial cells (MCF‐7) when the cells are incubated with dextran coated iron oxide nanoparticles that contain tumor‐homing F3 peptides, where the tumor‐homing F3 peptide specifically bound to nucleolin receptors that are overexpressed in cancer breast cells.     

Co‐Delivery of Doxorubicin and siRNA with Reduction and pH Dually Sensitive Nanocarrier for Synergistic Cancer Therapy

Drug resistance is the greatest challenge in clinical cancer chemotherapy. Co‐delivery of chemotherapeutic drugs and siRNA to tumor cells is a vital means to silence drug resistant genes during the course of cancer chemotherapy for an improved chemotherapeutic effect. This study aims at effective co‐delivery of siRNA and anticancer drugs to tumor cells. A ternary block copolymer PEG‐PAsp(AED)‐PDPA consisting of pH‐sensitive poly(2‐(diisopropyl amino)ethyl methacrylate) (PDPA), reduction‐sensitive poly(N‐(2,2′‐dithiobis(ethylamine)) aspartamide) PAsp(AED), and poly(ethylene glycol) (PEG) is synthesized and assembled into a core‐shell structural micelle which encapsulated doxorubicin (DOX) in its pH‐sensitive core and the siRNA‐targeting anti‐apoptosis BCL‐2 gene (BCL‐2 siRNA) in a reduction‐sensitive interlayer. At the optimized size and zeta potential, the nanocarriers loaded with DOX and BCL‐2 siRNA may effectively accumulate in the tumor site via blood circulation. Moreover, the dual stimuli‐responsive design of micellar carriers allows microenviroment‐specific rapid release of both DOX and BCL‐2 siRNA inside acidic lysosomes with enriched reducing agent, glutathione (GSH, up to 10 mm ). Consequently, the expression of anti‐apoptotic BCL‐2 protein induced by DOX treatment is significantly down‐regulated, which results in synergistically enhanced apoptosis of human ovarian cancer SKOV‐3 cells and thus dramatically inhibited tumor growth.     

Dual‐pH Sensitive Charge‐Reversal Polypeptide Micelles for Tumor‐Triggered Targeting Uptake and Nuclear Drug Delivery

A novel dual‐pH sensitive charge‐reversal strategy is designed to deliver antitumor drugs targeting to tumor cells and to further promote the nuclei internalization by a stepwise response to the mildly acidic extracellular pH (≈6.5) of a tumor and endo/lysosome pH (≈5.0). Poly(l ‐lysine)‐block–poly(l ‐leucine) diblock copolymer is synthesized and the lysine amino residues are amidated by 2,3‐dimethylmaleic anhydride to form β‐carboxylic amide, making the polypeptides self‐assemble into negatively charged micelles. The amide can be hydrolyzed when exposed to the mildly acidic tumor extracellular environment, which makes the micelles switch to positively charged and they are then readily internalized by tumor cells. A nuclear targeting Tat peptide is further conjugated to the polypeptide via a click reaction. The Tat is amidated by succinyl chloride to mask its positive charge and cell‐penetrating function and thus to inhibit nonspecific cellular uptake. After the nanoparticles are internalized into the more acidic intracellular endo/lysosomes, the Tat succinyl amide is hydrolyzed to reactivate the Tat nuclear targeting function, promoting nanoparticle delivery into cell nuclei. This polypeptide nanocarrier facilitates tumor targeting and nuclear delivery simultaneously by simply modifying the lysine amino residues of polylysine and Tat into two different pH‐sensitive β‐carboxylic amides.     

In Vivo Environment‐Adaptive Nanocomplex with Tumor Cell–Specific Cytotoxicity Enhances T Cells Infiltration and Improves Cancer Therapy

Drug delivery strategies possessing selectivity for cancer cells are eagerly needed in therapy of metastatic breast cancer. In this study, the chemotherapeutic agent, docetaxel (DTX), is conjugated onto heparan sulfate (HS). Aspirin (ASP), which has the activity of anti‐metastasis and enhancing T cells infiltration in tumors, is encapsulated into the HS‐DTX micelle. Then the cationic polyethyleneimine (PEI)‐polyethylene glycol (PEG) copolymer binds to HS via electrostatic force, forming the ASP‐loaded HS‐DTX micelle (AHD)/PEI‐PEG nanocomplex (PAHD). PAHD displays long circulation behavior in blood due to the PEG shell. Under the tumor microenvironment with weakly acidic pH, PEI‐PEG separates from AHD, and the free cationic PEI‐PEG facilitates the cellular uptake of AHD by increasing permeability of cell membranes. Then the overexpressed heparanase degrades HS, releasing ASP and DTX. PAHD shows specific toxicity toward tumor cells but not normal cells, with advanced activity of inhibiting tumor growth and lung metastasis in 4T1 tumor‐bearing mice. The number of CD8⁺ T cells in tumor tissues is also increased. Therefore, PAHD can become an efficient drug delivery system for breast cancer treatment.     

Loading and Release Mechanism of Red Clover Necrotic Mosaic Virus Derived Plant Viral Nanoparticles for Drug Delivery of Doxorubicin

Loading and release mechanisms of Red clover necrotic mosaicvirus (RCNMV) derived plant viral nanoparticle (PVN) are shown for controlled delivery of the anticancer drug, doxorubicin (Dox). Previous studies demonstrate that RCNMV's structure and unique response to divalent cation depletion and re‐addition enables Dox infusion to the viral capsid through a pore formation mechanism. However, by controlling the net charge of RCNMV outer surface and accessibility of RCNMV interior cavity, tunable release of PVN is possible via manipulation of the Dox loading capacity and binding locations (external surface‐binding or internal capsid‐encapsulation) with the RCNMV capsid. Bimodal release kinetics is achieved via a rapid release of surface‐Dox followed by a slow release of encapsulated Dox. Moreover, the rate of Dox release and the amount of released Dox increases with an increase in environmental pH or a decrease in concentration of divalent cations. This pH‐responsive Dox release from PVN is controlled by Fickian diffusion kinetics where the release rate is dependent on the location of the bound or loaded active molecule. In summary, controllable release of Dox‐loaded PVNs is imparted by 1) formulation conditions and 2) driven by the capsid's pH‐ and ion‐ responsive functions in a given environment.