Simple and Efficient Targeted Intracellular Protein Delivery with Self‐Assembled Nanovehicles for Effective Cancer Therapy

Protein therapy offers promising prospects for the treatment of various important diseases, thus it is highly desirable to develop a robust carrier that can deliver active proteins into cells. The development of a novel protein delivery platform based on the self‐assembly of multiarmed amphiphilic cyclodextrins (CDEH) is reported. CDEH can self‐assemble into nanoparticles in aqueous solution and achieve superior encapsulation of protein (loading capacity > 30% w/w) simply by mixing with protein solution without introducing any subsequent cumbersome steps that may inactivate proteins. More importantly, CDEH nanovehicles can be easily further modified with various targeting groups based on host–guest complexation. Using saporin as a therapeutic protein, AS1411‐aptamer‐modified CDEH nanovehicles can preferentially accumulate in tumors and efficiently inhibit tumor growth in a MDA‐MB‐231 xenograft mouse model. Moreover, folate‐targeted CDEH nanovehicles can also deliver Cas9 protein and Plk1‐targeting sgRNA into Hela cells, leading to 47.1% gene deletion and 64.1% Plk1 protein reduction in HeLa tumor tissue, thereby effectively suppressing the tumor progression. All these results indicate the potential of targeted CDEH nanovehicles in intracellular protein delivery for improving protein therapeutics.     

IL4‐Receptor‐Targeted Dual Antitumoral Apoptotic Peptide—siRNA Conjugate Lipoplexes

Targeted delivery remains the major limitation in the development of small interfering RNA (siRNA) therapeutics. The successful siRNA multistep delivery requires precise carriers of substantial complexity. To achieve this, a monodisperse carrier is presented, synthesized by solid‐phase supported chemistry. The sequence‐defined assembly contains two oleic acids attached to a cationizable oligoaminoamide backbone in T‐shape configuration, and a terminal azide functionality for coupling to the atherosclerotic plaque‐specific peptide‐1 (AP‐1) as the cell targeting ligand for interleukin‐4 receptor (IL‐4R) which is overexpressed in a variety of solid cancers. For combined cytosolic delivery with siRNA, different apoptotic peptides (KLK, BAK, and BAD) are covalently conjugated via bioreversible disulfide linkage to the 5′‐end of the siRNA sense strand. siRNA‐KLK conjugates provide the highest antitumoral potency. The optimized targeted carrier is complexed with dual antitumoral siEG5‐KLK conjugates. The functionality of each subdomain is individually confirmed. The lipo‐oligomer confers stable assembly of siRNA conjugates into spherical 150–250 nm sized nanoparticles. Click‐shielding with dibenzocyclootyne‐PEG‐AP‐1 (DBCO‐PEG‐AP‐1) mediates an IL‐4R‐specific cell targeting and gene silencing in tumor cells. Most importantly, formulation of the siEG5‐KLK conjugate displays enhanced apoptotic tumor cell killing due to the combined effect of mitotic arrest by EG5 gene silencing and mitochondrial membrane disruption by KLK.     

pH‐Tunable Endosomolytic Oligomers for Enhanced Nucleic Acid Delivery

Oligomeric sulfonamides (OSAs) are explored as a tool for the effective endosomal release of polyplexes or delivery of nucleic acid. The OSAs tested in this study show varying proton‐buffering regions and pH‐dependent solubility transitions within the endosomal pH range, and are influenced by the pK_a value and hydrophobicity of a given sulfonamide group. In addition, OSA presents negligible toxicity. The oligomers are added to the nucleic acid solution for polyplex formation with positively charged polymeric nucleic acid carriers. The resulting nanoscale, positively charged, and OSA‐incorporated poly(L ‐lysine) (PLL)/DNA complexes (OSA‐polyplexes) show a 4–55‐fold increase in in vitro gene expression compared to PLL/DNA (control), depending upon the cell line and the nature of the used OSA. In cellular uptake and intracellular trafficking studies using pH‐sensitive or pH‐insensitive dye‐labeled DNAs, there is no significant difference in the amount of DNA uptake using OSA polyplexes and PLL/DNA. However, OSA–polyplexes induce a broader intracellular distribution of the DNA than PLL/DNA complexes do. These results, coupled with the enhanced DNA transfection using OSA–polyplexes, indicate a mechanism by which OSA induces endosomal release of polyplexes and/or nucleic acids. The findings suggest that OSA could enhance polymer‐based nucleic acid delivery. Furthermore, such materials offer significant potential for effective cytosolic delivery of chemical, biological, and diagnostic therapeutics.     

Charge‐Reversal Drug Conjugate for Targeted Cancer Cell Nuclear Drug Delivery

DNA‐toxin anticancer drugs target nuclear DNA or its associated enzymes to elicit their pharmaceutical effects, but cancer cells have not only membrane‐associated but also many intracellular drug‐resistance mechanisms that limit their nuclear localization. Thus, delivering such drugs directly to the nucleus would bypass the drug‐resistance barriers. The cationic polymer poly(L ‐lysine) (PLL) is capable of nuclear localization and may be used as a drug carrier for nuclear drug delivery, but its cationic charges make it toxic and cause problems in in‐vivo applications. Herein, PLL is used to demonstrate a pH‐triggered charge‐reversal carrier to solve this problem. PLL's primary amines are amidized as acid‐labile β‐carboxylic amides (PLL/amide). The negatively charged PLL/amide has a very low toxicity and low interaction with cells and, therefore, may be used in vivo. But once in cancer cells' acidic lysosomes, the acid‐labile amides hydrolyze into primary amines. The regenerated PLL escapes from the lysosomes and traverses into the nucleus. A cancer‐cell targeted nuclear‐localization polymer–drug conjugate has, thereby, been developed by introducing folic‐acid targeting groups and an anticancer drug camptothecin (CPT) to PLL/amide (FA‐PLL/amide‐CPT). The conjugate efficiently enters folate‐receptor overexpressing cancer cells and traverses to their nuclei. The CPT conjugated to the carrier by intracellular cleavable disulfide bonds shows much improved cytotoxicity.     

Multifunctional Mesoporous Silica Nanoparticles for Cancer‐Targeted and Controlled Drug Delivery

Multifunctional mesoporous silica nanoparticles are developed in order to deliver anticancer drugs to specific cancer cells in a targeted and controlled manner. The nanoparticle surface is functionalized with amino‐β‐cyclodextrin rings bridged by cleavable disulfide bonds, blocking drugs inside the mesopores of the nanoparticles. Poly(ethylene glycol) polymers, functionalized with an adamantane unit at one end and a folate unit at the other end, are immobilized onto the nanoparticle surface through strong β‐cyclodextrin/adamantane complexation. The non‐cytotoxic nanoparticles containing the folate targeting units are efficiently trapped by folate‐receptor‐rich HeLa cancer cells through receptormmediated endocytosis, while folate‐receptor‐poor human embryonic kidney 293 normal cells show much lower endocytosis towards nanoparticles under the same conditions. The nanoparticles endocytosed by the cancer cells can release loaded doxorubicin into the cells triggered by acidic endosomal pH. After the nanoparticles escape from the endosome and enter into the cytoplasm of cancer cells, the high concentration of glutathione in the cytoplasm can lead to the removal of the β‐cyclodextrin capping rings by cleaving the pre‐installed disulfide bonds, further promoting the release of doxorubicin from the drug carriers. The high drug‐delivery efficacy of the multifunctional nanoparticles is attributed to the co‐operative effects of folate‐mediated targeting and stimuli‐triggered drug release. The present delivery system capable of delivering drugs in a targeted and controlled manner provides a novel platform for the next generation of therapeutics.     

Cancer‐Targeted Monodisperse Mesoporous Silica Nanoparticles as Carrier of Ruthenium Polypyridyl Complexes to Enhance Theranostic Effects

Mesoporous silica nanoparticles (MSNs) have been well‐demonstrated as excellent carriers for anticancer drug delivery. Presented here is a cancer‐targeted MSNs drug delivery system that allows the direct fluorescence monitoring of the cellular uptake and localization of theranostic agents in cancer cells. Specifically, the anticancer action mechanisms of RGD peptide‐functionalized MSNs carrying ruthenium polypyridyl complexes (RuPOP@MSNs) are elucidated in detail. RGD peptide surface decoration significantly enhances the cellular uptake of the nanoparticles through receptor‐mediated endocytosis, and increases the selectivity between cancer and normal cells. RuPOP@MSNs exhibits unprecedented enhanced cytotoxicity toward cancer cells overexpressing integrin receptor, which is significantly higher than that of free RuPOP, through induction of apoptosis. The important contribution of extrinsic pathway to cell apoptosis is confirmed by increase in expression levels of death receptors, activation of caspase‐8 and truncation of Bid. The internalized nanoparticles release free RuPOP into the cytoplasm, where they modulate the phosphorylation of p53, AKT, and MAPKs pathways to promote cell apoptosis. Moreover, the strong autofluorescence of RuPOP permits the direct monitoring of drug delivery, and extends the power of theranostics to subcellular level. Taken together, this study provides an effective strategy for the design and development of cancer‐targeted theranostic agents.     

Supramolecular Assembly of Aminoethylene‐Lipopeptide PMO Conjugates into RNA Splice‐Switching Nanomicelles

Phosphorodiamidate morpholino oligomers (PMOs) are oligonucleotide analogs that can be used for therapeutic modulation of pre‐mRNA splicing. Similar to other classes of nucleic acid‐based therapeutics, PMOs require delivery systems for efficient transport to the intracellular target sites. Here, artificial peptides based on the oligo(ethylenamino) acid succinyl‐tetraethylenpentamine (Stp), hydrophobic modifications, and an azide group are presented, which are used for strain‐promoted azide‐alkyne cycloaddition conjugation with splice‐switching PMOs. By systematically varying the lead structure and formulation, it is determined that the type of contained fatty acid and supramolecular assembly have a critical impact on the delivery efficacy. A compound containing linolenic acid with three cis double bonds exhibits the highest splice‐switching activity and significantly increases functional protein expression in pLuc/705 reporter cells in vitro and after local administration in vivo. Structural and mechanistic studies reveal that the lipopeptide PMO conjugates form nanoparticles, which accelerate cellular uptake and that the content of unsaturated fatty acids enhances endosomal escape. In an in vitro Duchenne muscular dystrophy exon skipping model using H2K‐mdx52 dystrophic skeletal myotubes, the highly potent PMO conjugates mediate significant splice‐switching at very low nanomolar concentrations. The presented aminoethylene‐lipopeptides are thus a promising platform for the generation of PMO‐therapeutics with a favorable activity/toxicity profile.     

Effective and Selective Anti‐Cancer Protein Delivery via All‐Functions‐in‐One Nanocarriers Coupled with Visible Light‐Responsive,Reversible Protein Engineering

Efficient intracellular delivery of protein drugs and tumor‐specific activation of protein functions are critical toward anti‐cancer protein therapy. However, an omnipotent protein delivery system that can harmonize the complicated systemic barriers as well as spatiotemporally manipulate protein function is lacking. Herein, an “all‐functions‐in‐one” nanocarrier doped with photosensitizer (PS) is developed and coupled with reactive oxygen species (ROS)‐responsive, reversible protein engineering to realize cancer‐targeted protein delivery, and spatiotemporal manipulation of protein activities using long‐wavelength visible light (635 nm) at low power density (5 mW cm^?2). Particularly, RNase A is caged with H₂O₂‐cleavable phenylboronic acid to form 4‐nitrophenyl 4‐(4,4,5,5‐tetramethyl‐1,3,2‐dioxaborolan‐2‐yl)benzyl carbonate (NBC)‐modified RNase (RNBC), which is encapsulated in acid‐degradable, ketal‐crosslinked PEI (KPEI)‐based nanocomplexes (NCs) coated with PS‐modified hyaluronic acid (HA). Such NCs harmonize the critical processes for protein delivery, wherein HA coating renders NCs with long blood circulation and cancer cell targeting, and KPEI enables endosomal escape as well as acid‐triggered intracellular RNBC release. Tumor‐specific light irradiation generates H₂O₂ to kill cancer cells and restore the protein activity, thus achieving synergistic anti‐cancer efficacy. It is the first time to photomanipulate protein functions by coupling ROS‐cleavable protein caging with PS‐mediated ROS generation, and the “all‐functions‐in‐one” nanocarrier represents a promising example for the programmed anti‐cancer protein delivery.     

Selective Photothermal Tumor Therapy Using Nanodiamond‐Based Nanoclusters with Folic Acid

This paper describes the fabrication and evaluation of folic acid (FA)‐conjugated nanodiamond (ND) nanoclusters for selective photothermal tumor therapy. ND nanoclusters with surface carboxyl groups are aminated using ethylenediamine and conjugated with FA via carbodiimide chemistry. The temperature of an aqueous ND dispersion (10 μg mL^?1) is increased to 54 °C upon laser exposure for 5 min. FA‐ND nanoclusters are preferentially taken up by KB cells (folate receptor positive) compared to WI‐38 (folate receptor negative) cells, suggesting specificity for tumor cells that overexpress folate receptors. Cell viability tests reveal that FA‐ND nanoclusters effectively and selectively ablate KB cells upon near‐infrared (NIR) laser exposure. In addition, fluorescence microscopy images confirm that only KB cells treated with FA‐ND nanoclusters are ablated in a spot (200 μm in diameter) by NIR laser exposure. In an animal model, a large amount of FA‐ND nanoclusters is accumulated into tumor tissue, resulting in dramatically reduced tumor volume post‐NIR laser exposure as compared to ND nanoclusters.     

Inorganic Drug‐Delivery Nanovehicle Conjugated with Cancer‐Cell‐Specific Ligand

The surface of layered double hydroxide nanoparticles, a potential drug‐delivery nanovehicle, is modified with the cancer‐cell‐specific ligand, folic acid. The surface modification is successfully accomplished through step‐by‐step coupling reactions with aminopropyltriethoxysilane and 1‐ethyl‐3‐(3‐dimethyl aminopropyl)‐carbodiimide. In order to evaluate the cancer‐cell targeting effect of folic‐acid‐grafted layered double hydroxide utilizing fluorescence‐related assay, both layered double hydroxide with and without folic acid moiety are labeled with fluorescein 5′‐isothiocyanate. The uptake of layered double hydroxide and folic acid conjugated into KB and A549 cells is visualized using fluorescence microscopy and measured by flow cytometry. Both chemical and biological assay results demonstrate that the folic acid molecules are indeed conjugated to the surface of layered double hydroxide and thus the selectivity of nanovehicles to cancer cells overexpressing folate receptors increases. In this study, it is suggested that layered double hydroxide nanoparticles can be used as drug‐delivery carriers with a targeting function due to the chemical conjugation with specific ligand.     

Nanogel-Facilitated Protein Intracellular Specific Degradation through Trim-Away

The recently discovered “Trim-Away” mechanism opens a new window for fast and selective degradation of endogenous proteins. However, the in vivo and clinical application of this approach is hindered by the requirement of special skills and equipment needed for the intracellular delivery of antibodies. Here, an antibody conjugated polymer nanogel system, nano gel-facilitate d pr otein intra cellular s pecific de gr adation (Nano-ERASER), for intracellular delivery and release of antibody, and degradation of a specific endogenous protein is developed. After being delivered into cells, the antibody is released and forms a complex with its target protein, and subsequently binds to the Fc receptor of Tripartite motif 21 (TRIM21). The resulting complex of target protein/antibody/TRIM21 is then degraded by the proteasome. The efficacy of Nano-ERASER is validated by depleting GFP protein in a GFP expressing cell line. Furthermore, Nano-ERASER successfully degrades the coatomer protein complex ζ1, a vital protein for cancer cells, and kills those cells while sparing normal cells. Benefitting from its convenience and targeted delivery merit, Nano-ERASER technique is promising in providing a reliable tool for endogenous protein function study as well as paves the way for novel antibody-based Trim-Away therapeutic modalities for cancer and other diseases.     

Highly Biocompatible Carbon Nanodots for Simultaneous Bioimaging and Targeted Photodynamic Therapy In Vitro and In Vivo

Photosensitizers (PSs) are light‐sensitive molecules that are highly hydrophobic, which poses a challenge to their use for targeted photodynamic therapy. Hence, considerable efforts have been made to develop carriers for the delivery of PSs. Herein, a novel design is described of highly biocompatible, fluorescent, folic acid (FA)‐functionalized carbon nanodots (CDs) as carriers for the PS zinc phthalocyanine (ZnPc) to achieve simultaneous biological imaging and targeted photodynamic therapy. FA is modified on PEG‐­passivated CDs (CD‐PEG) for targeted delivery to FA‐positive cancer cells, and ZnPc is loaded onto CD‐PEG‐FA via π–π stacking interactions. CD‐PEG‐FA/ZnPc exhibits excellent targeted delivery of the PS, leading to simultaneous imaging and significant targeted photodynamic therapy after irradiation in vitro and in vivo. The present CD‐based targeted delivery of PSs is anticipated to offer a convenient and effective platform for enhanced photodynamic therapy to treat cancers in the near future.     

Integrated Combination Treatment Using a “Smart” Chemotherapy and MicroRNA Delivery System Improves Outcomes in an Orthotopic Colorectal Cancer Model

Mesoporous silica nanoparticles (MSN) can load and deliver potentially synergistic anticancer agents such as small molecule cytotoxics (like doxorubicin, DOX) and nucleic acids (like microRNA, miRNA). However, these cargos have different underlying chemical properties so overcoming respective intracellular delivery barriers is a key consideration. Strategies to deliver DOX from MSN frequently employ pH‐driven mechanisms that are restricted to the acidic environment of lysosomes. Conversely, strategies to deliver miRNA make use of approaches that deliberately compromise lysosomal membrane integrity to enable cytosolic delivery of the payload. To reconcile these two needs (lysosomal delivery of DOX and intracellular delivery of miRNA), a new methodology by “weaving” polyethylenimine on the MSN surface through disulfide bonds to achieve superior delivery of chemotherapy (DOX) and miRNA therapy (using miRNA‐145) is developed. Furthermore, an active targeting strategy based on a peptide ligand with affinity to glucose‐regulated protein 78 (GRP78), a cell surface protein overexpressed in colorectal carcinoma, is developed. The active targeting approach results in enhanced synergistic antitumor effect both in vitro and in vivo in an orthotopic murine model of colorectal cancer. Taken together, this work demonstrates the capability and advantages of “smart” MSN delivery systems to deliver anticancer cargo appropriately to targeted cancer cells.     

Doxorubicin‐Conjugated Immuno‐Nanoparticles for Intracellular Anticancer Drug Delivery

A polymeric nanoparticle comprised of surface furan groups is used to bind, by Diels–Alder (DA) coupling chemistry, both targeting anti‐human epidermal growth factor receptor 2 (anti‐HER2) antibodies and chemotherapeutic doxorubicin (DOX) for targeted, intracellular delivery of DOX. In this new approach for delivery, where both chemotherapeutic and targeting ligand are attached, for the first time, to the surface of the delivery vehicle, the nuclear localization of DOX in HER2‐overexpressing breast cancer SKBR‐3 cells is demonstrated, as determined by confocal laser scanning microscopy. Flow cytometric analysis shows that the conjugated DOX maintains its biological function and induces similar apoptotic progression in SKBR‐3 cells as free DOX. The viable cell counts of SKBR‐3 cancer cells following incubation with different nanoparticle formulations demonstrates that the combined DOX and anti‐HER2 nanoparticle is more efficacious than the nanoparticle formulation with either DOX or anti‐HER2 alone. While free DOX shows similar cytotoxicity against both cancerous SKBR‐3 cells and healthy HMEC‐1 cells, the combined DOX‐anti‐HER2 nanoparticle is significantly more cytotoxic against SKBR‐3 cells than HMEC‐1 cells, suggesting the benefit of nanoparticle‐conjugated DOX for cell type‐specific targeting. The DOX‐conjugated immuno‐nanoparticle represents an entirely new method for localized co‐delivery of chemotherapeutics and antibodies.     

Structure‐Invertible Nanoparticles for Triggered Co‐Delivery of Nucleic Acids and Hydrophobic Drugs for Combination Cancer Therapy

Here, a new type of structure‐invertible, redox‐responsive polymeric nanoparticle for the efficient co‐delivery of nucleic acids and hydrophobic drugs in vitro and in vivo is reported for the first time, to combat the major challenges facing combination cancer therapy. The co‐delivery vector, which is prepared by conjugating branched poly(ethylene glycol) with dendrimers of two generations (G2) through disulfide linkages, is able to complex nucleic acids and load hydrophobic drugs with high loading capacity through structure inversion. The cleavage of disulfide linkages at intracellular glutathione‐rich reduction environment significantly decreases the cytotoxicity, and promotes more efficient drug release and gene transfection in vitro and in vivo. The co‐delivery carrier also displays enhanced endosomal escape capability and improved serum stability in vitro as compared with G2, and exhibits prolonged residence time and stronger transfection activity in vivo. Most importantly, co‐delivery of doxorubicin (DOX) and B‐cell lymphoma 2 (Bcl‐2) small interfering RNA (siRNA) exerts a combinational effect against tumor growth in murine tumor models in vivo, which is much more effective than either DOX or Bcl‐2 siRNA‐based monotherapy. The structure‐invertible nanoparticles may constitute a promising stimuli‐responsive system for the efficacious co‐delivery of multiple cargoes in future clinical applications of combination cancer therapies.     

Intranuclear Photosensitizer Delivery and Photosensitization for Enhanced Photodynamic Therapy with Ultralow Irradiance

Photodynamic therapy (PDT) is a well‐established clinical treatment modality for various diseases. However, reactive oxygen species (ROS) generated by photosensitizers(PS) under proper irradiation exhibits the extremely short life span (<200 ns) and severely limited diffusion distance (20 nm), so the damage of ROS to biomolecules, especially DNA, is strongly confined to the immediate vicinity of ROS generation. In this report, an efficient nuclear‐targeted delivery strategy is proposed by using TAT and RGD peptides co‐conjugated mesoporous silica nanoparticles (MSNs) as PS carriers. The conjugation of TAT peptides enable the nuclear penetration of MSNs for efficient accumulation of PS inside nuclei. The intranuclear‐accumulated PS can generate ROS upon irradiation right inside nuclei to destroy DNA instantaneously. For the purpose of in vivo applications, the co‐conjugated RGD peptides endow the nuclear‐targeted delivery system with specific binding and recognition to tumor vasculature and tumor cell membranes for significantly enhanced specificity and reduced side effects. Through intravenous injection of these nanosystems in tumor‐bearing mice at a rather low PS dose of 2 mg/kg, tumor growth is efficiently inhibited by an extremely low irradiation dose of 6 J/cm². This work presents a new paradigm for specific PDT with high efficacy and low side effects in vivo.     

A Hybrid Carrier System Based on Origami Nanostrucutures and Layer‐by‐Layer Microparticles

Recent progress in DNA nanotechnology allows the fabrication of 3D structures that can be loaded with a large variety of molecular cargos and even be responsive to external stimuli. This makes the use of DNA nanostructures a promising approach for applications in nanomedicine and drug delivery. However, their low stability in the extra‐ and intracellular environment as well as low cellular uptake rates and release rates from endosomes into the cytoplasm hamper the efficient and targeted use of DNA nanostructures in medical applications. Here, such major obstacles are overcome by integrating DNA origami nanostructures into superordinated layer‐by‐layer based microparticles made from biopolymers. The modular assembly of the polymer layer allows a high‐density incorporation of the DNA structures at different depth. This enables controllable protection of the DNA nanostructures over extended durations in a broad range of extra‐ and intracellular conditions without compromising the cell viability. Furthermore, by producing protein‐complexed DNA nanostructures it is demonstrated that molecular cargo can be conveniently integrated into the developed hybrid system. This work provides the basis for a new multistage carrier system allowing for an efficient and protected transport of active agents inside responsive DNA nanostructures.     

Biocompatible,Uniform, and Redispersible Mesoporous Silica Nanoparticles for Cancer‐Targeted Drug Delivery In Vivo

Engineering multifunctional nanocarriers for targeted drug delivery shows promising potentials to revolutionize the cancer chemotherapy. Simple methods to optimize physicochemical characteristics and surface composition of the drug nanocarriers need to be developed in order to tackle major challenges for smooth translation of suitable nanocarriers to clinical applications. Here, rational development and utilization of multifunctional mesoporous silica nanoparticles (MSNPs) for targeting MDA‐MB‐231 xenograft model breast cancer in vivo are reported. Uniform and redispersible poly(ethylene glycol)‐incorporated MSNPs with three different sizes (48, 72, 100 nm) are synthesized. They are then functionalized with amino‐β‐cyclodextrin bridged by cleavable disulfide bonds, where amino‐β‐cyclodextrin blocks drugs inside the mesopores. The incorporation of active folate targeting ligand onto 48 nm of multifunctional MSNPs (PEG‐MSNPs48‐CD‐PEG‐FA) leads to improved and selective uptake of the nanoparticles into tumor. Targeted drug delivery capability of PEG‐MSNPs48‐CD‐PEG‐FA is demonstrated by significant inhibition of the tumor growth in mice treated with doxorubicin‐loaded nanoparticles, where doxorubicin is released triggered by intracellular acidic pH and glutathione. Doxorubicin‐loaded PEG‐MSNPs48‐CD‐PEG‐FA exhibits better in vivo therapeutic efficacy as compared with free doxorubicin and non‐targeted nanoparticles. Current study presents successful utilization of multifunctional MSNP‐based drug nanocarriers for targeted cancer therapy in vivo.     

A Smart Nanoassembly for Multistage Targeted Drug Delivery and Magnetic Resonance Imaging

Efficient delivery of DNA‐toxin anticancer drugs into nucleus of targeted tumor cells while simultaneously minimizing the side effects to normal tissue is a major challenge for cancer therapy. Herein, a multistage continuous targeting strategy based on magnetic mesoporous silica nanoparticles to overcome the challenge is demonstrated. At the initial‐stage, the magnetic nanoparticle is capable of efficiently accumulating in tumor tissue guided by magnet. Following by the magnetic targeting, the targeting ligand gets it right into the cancer cell by receptor‐mediated endocytosis. Accompanied by endocytosis into the lysosomes, the nanoparticle reverses its surface charge from negative to positive which leads to the separation of charge‐conversional polymer from the nanoparticle to re‐expose the nuclear‐targeting TAT peptide. Finally, TAT peptide facilitates the carriers to enter nucleus and the DNA‐toxin camptothecin can inhibit topoisomerase I to induce cell apoptosis. Furthermore, the nano‐drug delivery system can be simultaneously used as predominant contrast agents for magnetic resonance imaging. This proof of concept might open the door to a new generation of carrier materials in the fields of targeted drug transport platform for cancer theranostics.     

Virus‐Inspired Mimics Based on Dendritic Lipopeptides for Efficient Tumor‐Specific Infection and Systemic Drug Delivery

Herein, multifunctional mimics of viral architectures and infections self‐assembled from tailor‐made dendritic lipopeptides for programmed targeted drug delivery are reported. These viral mimics not only have virus‐like components and nanostructures, but also possess virus‐like infections to solid tumor and tumor cells. Encouragingly, the viral mimics provide the following distinguished features for tumor‐specific systemic delivery: i) stealthy surface to resist protein interactions and prolong circulation time in blood, ii) well‐defined nanostructure for passive targeting to solid tumor site, iii) charge‐tunable shielding for tumor extracellular pH targeting, iv) receptor‐mediated targeting to enhance tumor‐specific uptake, and v) supramolecular lysine‐rich architectures mimicking viral subcellular targeting for efficient endosomal escape and nuclear delivery. This bioinspired design make in vivo tumor suppression by drug‐loaded viral mimics against BALB/c mice bearing 4T1 tumor greatly exceed the positive control group (more than three times). More importantly, viral mimics hold great potentials to reduce side effects and decrease tumor metastasis after systemic administration.