Effect of intratumoral injection on the biodistribution and therapeutic potential of novel chemophor EL-modified single-walled nanotube loading doxorubicin

The purpose of this study is to evaluate in vivo efficacy and loco-regional distribution of a doxorubicin (DOX)-loaded Polyoxyl 35 Castor Oil (Cremophor EL, CrEL) noncovalent modified single-walled carbon nanotubes (SWNTs) formulation in a sarcoma tumor model after intratumoral injection. The drug loaded SWNTs were successfully prepared via physical absorption, which was confirmed by UV-vis-NIR absorbance spectra and dynamic light scattering assay. Solid tumor models were obtained by injecting mouse sarcoma 180 cells into the thighs of ICR mice. CrEL-SWNTs-DOX, CrEL-SWNTs, free DOX and saline (control) were intratumorally injected after 5 days post transplantation. The biodistribution studies demonstrated that intratumoral delivery of CrEL-SWNTs-DOX resulted in longer drug retention time in tumor, higher tumor level (27.6-fold than that of free DOX), as well as less accumulation in other solid tissues, especially in heart. Furthermore, in vivo anti-tumor activity results showed that CrEL-SWNTs-DOX could effectively suppress the tumor growth than free DOX and the control, attributing to its enhanced intratumoral DOX level. The histopathological findings revealed that the new carbon nanomaterials were a safe vehicle for topical drug delivery systems. It is concluded that this noncovalent modification of carbon nanotubes by CrEL for anticancer agents might be a promising alternative for cancer treatment.     

pH-Controlled Delivery of Doxorubicin to Cancer Cells, Based on Small Mesoporous Carbon Nanospheres

Mesoporous carbon nanospheres (MCNs) with small diameters of ≈90 nm are developed as an efficient transmembrane delivery vehicle of an anticancer drug, doxorubicin (DOX). MCNs exhibit a high loading capacity toward DOX due to hydrophobic interactions and the supramolecular π stacking between DOX and the carbonaceous structures, on which the pH-dependent drug release are successfully achieved. Specifically, DOX can be loaded onto MCNs in basic solution and in a physiological pH range, while release occurs in acidic solution in its ionized state. By effective passive and active targeting, MCNs can be readily internalized into HeLa cells, where the carried DOX can be efficiently released in the acidic microenvironment of the tumors for further therapy. The endocytosis and cytotoxicity of DOX@MCNs toward HeLa cells are investigated by confocal microscopy and MTT assay. This smart pH-dependent drug loading and release property of DOX@MCNs makes it possible to reduce the cytotoxicity to normal tissues during circulation in the body since the normal physiological pH is ≈7.4.     

Effect of intratumoral injection on the biodistribution and therapeutic potential of novel chemophor EL-modified single-walled nanotube loading doxorubicin

The purpose of this study is to evaluate in vivo efficacy and loco-regional distribution of a doxorubicin (DOX)-loaded Polyoxyl 35 Castor Oil (Cremophor EL, CrEL) noncovalent modified single-walled carbon nanotubes (SWNTs) formulation in a sarcoma tumor model after intratumoral injection. The drug loaded SWNTs were successfully prepared via physical absorption, which was confirmed by UV-vis-NIR absorbance spectra and dynamic light scattering assay. Solid tumor models were obtained by injecting mouse sarcoma 180 cells into the thighs of ICR mice. CrEL-SWNTs-DOX, CrEL-SWNTs, free DOX and saline (control) were intratumorally injected after 5 days post transplantation. The biodistribution studies demonstrated that intratumoral delivery of CrEL-SWNTs-DOX resulted in longer drug retention time in tumor, higher tumor level (27.6-fold than that of free DOX), as well as less accumulation in other solid tissues, especially in heart. Furthermore, in vivo anti-tumor activity results showed that CrEL-SWNTs-DOX could effectively suppress the tumor growth than free DOX and the control, attributing to its enhanced intratumoral DOX level. The histopathological findings revealed that the new carbon nanomaterials were a safe vehicle for topical drug delivery systems. It is concluded that this noncovalent modification of carbon nanotubes by CrEL for anticancer agents might be a promising alternative for cancer treatment.     

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.     

Intracellular uptake, trafficking and subcellular distribution of folate conjugated single walled carbon nanotubes within living cells

Herein we studied the uptake, trafficking and distribution of folate conjugated single walled carbon nanotubes (SWNTs) within living cells. SWNTs were noncovalently functionalized with chitosan and then linked with folate acid and fluorescence dye Alexa Fluor 488 (denoted FA-SWNTs). Hep G2 cells were cultured in vitro and incubated with FA-SWNTs at different levels. The FA-SWNTs exhibited a concentration-dependent uptake within Hep G2 cells, and Hep G2 cells were able to internalize FA-SWNTs via a folate receptor-mediated pathway. The distribution of nanotubes inside cells demonstrated that the FA-SWNTs only locate in the cytoplasm and not in nuclei, indicating the failure of transporting through the nuclear envelope. Transmission electron microscope (TEM) results showed the presence of FA-SWNTs in lysosomes and the discharge to extracellular space after incubation with nanotubes for 5?h. No obvious cellular death rate was observed when the concentration of nanotubes was below 50?μg?ml(-1). However, cells with FA-SWNT uptake showed a concentration-dependent apoptosis. These discoveries might be helpful for understanding the interaction of SWNTs and living cells.     

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.     

A Sequential Target‐Responsive Nanocarrier with Enhanced Tumor Penetration and Neighboring Effect In Vivo

Nanodrug‐based cancer therapy is impeded by poor penetration into deep tumor tissues mainly due to the overexpression of hyaluronic acid (HA) in the tumor extracellular matrix (ECM). Although modification of nanoparticles (NPs) with hyaluronidase (HAase) is a potent strategy, it remains challenging to get a uniform distribution of drug at the tumor site because of the internalization of NPs by the cells in the tumor and HA regeneration. Herein, an intelligent nanocarrier, which can release HAase in response to the acidic tumor microenvironment (pH 6.5) and perform a strong neighboring effect with size reduction to overcome the above two problems and accomplish drug deep tumor penetration in vivo, is reported. In this design, HAase is encapsulated on the surfaces of doxorubicin (DOX) preloaded ZnO‐DOX NPs using a charge convertible polymer PEG‐PAH‐DMMA (ZDHD). The polymer can release HAase to degrade HA in the tumor ECM (pH 6.5). ZnO‐DOX NPs can release DOX in lysosomes (pH 4.5) to induce cell apoptosis, and exert a neighboring effect with size reduction to infect neighboring cells. The hierarchical targeted release of HAase and drugs is demonstrated to enhance tumor penetration and decrease side effects in vivo. This work shows promise for further application of ZDHD NPs in cancer therapy.     

Active nanodiamond hydrogels for chemotherapeutic delivery

Nanodiamond materials can serve as highly versatile platforms for the controlled functionalization and delivery of a wide spectrum of therapeutic elements. In this work, doxorubicin hydrochloride (DOX), an apoptosis-inducing drug widely used in chemotherapy, was successfully applied toward the functionalization of nanodiamond materials (NDs, 2-8 nm) and introduced toward murine macrophages as well as human colorectal carcinoma cells with preserved efficacy. The adsorption of DOX onto the NDs and its reversible release were achieved by regulating Cl- ion concentration, and the NDs were found to be able to efficiently ferry the drug inside living cells. Comprehensive bioassays were performed to assess and confirm the innate biocompatibility of the NDs, via real-time quantitative polymerase chain reaction (RT-PCR), and electrophoretic DNA fragmentation as well as MTT analysis confirmed the functional apoptosis-inducing mechanisms driven by the DOX-functionalized NDs. We extended the applicability of the DOX-ND composites toward a translational context, where MTT assays were performed on the HT-29 colon cancer cell line to assess DOX-ND induced cell death and ND-mediated chemotherapeutic sequestering for potential slow/sustained released capabilities. These and other medically relevant capabilities enabled by the NDs forge its strong potential as a therapeutically significant nanomaterial.     

Lipase‐Triggered Water‐Responsive “Pandora's Box” for Cancer Therapy: Toward Induced Neighboring Effect and Enhanced Drug Penetration

Insufficient drug release as well as poor drug penetration are major obstacles for effective nanoparticles (NPs)‐based cancer therapy. Herein, the high aqueous instability of amorphous calcium carbonate (ACC) is employed to construct doxorubicin (DOX) preloaded and monostearin (MS) coated “Pandora's box” (MS/ACC–DOX) NPs for lipase‐triggered water‐responsive drug release in lipase‐overexpressed tumor tissue to induce a neighboring effect and enhance drug penetration. MS as a solid lipid can prevent potential drug leakage of ACC–DOX NPs during the circulatory process, while it can be readily be disintegrated in lipase‐overexpressed SKOV3 cells to expose the ACC–DOX core. The high aqueous instability of ACC will lead to burst release of the encapsulated DOX to induce apoptosis and cytotoxicity to kill the tumor cells. The liberated NPs from the dead or dying cells continue to respond to the ubiquitous aqueous environment to sufficiently release DOX once unpacked, like the “Pandora's box”, leading to severe cytotoxicity to neighboring cells (neighboring effect). Moreover, the continuously released free DOX molecules can readily diffused through the tumor extracellular matrix to enhance drug penetration to deep tumor tissue. Both effects contribute to achieve elevated antitumor benefits.     

Efficient delivery of antitumor drug to the nuclei of tumor cells by amphiphilic biodegradable poly(L-aspartic acid-co-lactic acid)/DPPE co-polymer nanoparticles

The use of biodegradable polymeric nanoparticles (NPs) for controlled drug delivery has shown significant therapeutic potential. Polyaspartic acid and polylactic acid are the most intensively studied biodegradable polymers. In the present study, novel amphiphilic biodegradable co-polymer NPs, poly(L-aspartic acid-co-lactic acid) with 1,2-dipalmitoyl-sn-glycero-3-phosphoethanolamine (DPPE) (poly(AA-co-LA)/DPPE) is synthesized and subsequently used to encapsulate an antitumor drug doxorubicin (DOX). The formulation parameters of the NPs are optimized to improve encapsulation efficiency. The resulting drug-loaded NPs possess better size homogeneity (polydispersity) and exhibit pH-responsive drug release profiles. Cellular viability assays indicate that the poly(AA-co-LA)/DPPE NPs did not induce cell death, whereas doxorubicin encapsulated NPs were cytotoxic to various types of tumor cells. In addition, the free NPs could not enter the cell nuclei after internalized in tumor cells. The DOX-loaded NPs exhibit efficient intracellular delivery in tumor cells with co-localization in lysosome and delay entering into the nucleus, which suggests a time- and pH-dependent drug release profile within cells. When applied to deliver chemotherapeutics to a mouse xenograft model of human lung adenocarcinoma, DOX-loaded NPs have a comparable antitumor activity with free DOX, and greatly reduce systemic toxicity and mortality. The delivery of cytotoxic drugs directly to the nucleus specifically within tumor cells is of great interest. These results demonstrate the feasibility of the application of the amphiphilic polyaspartic acid derivative, poly(AA-co-LA)/DPPE, as a nanocarrier for cell nuclear delivery of potent antitumor drugs.     

The synergistic effect of nanocrystal integration and process optimization on solar cell efficiency

This paper investigates the roles of semiconducting single-walled carbon nanotubes (SWNTs) and metallic SWNTs in the SWNT/poly(3-hexylthiophene) (P3HT)-based photovoltaic conversion system. SWNTs containing different fractions of semiconducting nanotubes were conjugated with P3HT by virtue of π-π interaction. The energy transfer and carrier transport mechanisms in the photovoltaic composites were experimentally investigated by optical absorption spectroscopy, photoluminescence spectroscopy and carrier mobility measurements. At low loading of SWNTs, a high percentage of semiconducting nanotubes result in diminished non-radiative decay of exciton and lower carrier mobility, causing higher open circuit voltage and lower photocurrent. At an optimized morphology, SWNT/P3HT/phenyl-C61-butyric acid methyl ester (PCBM) hybrid-based solar cells demonstrated much higher photocurrent than a reference solar cell (P3HT:PCBM) due to the improved carrier mobility. Further thermal annealing of the devices significantly increased the open circuit voltage to 610?mV, resulting in an 80% increase of power conversion efficiency in comparison to the reference solar cell. These results are expected to lay a foundation for the integration of various nanocrystals into solar cells for efficient photovoltaic conversion.     

Cyanine‐Anchored Silica Nanochannels for Light‐Driven Synergistic Thermo‐Chemotherapy

Smart nanoparticles are increasingly important in a variety of applications such as cancer therapy. However, it is still a major challenge to develop light‐responsive nanoparticles that can maximize the potency of synergistic thermo‐chemotherapy under light irradiation. Here, spatially confined cyanine‐anchored silica nanochannels loaded with chemotherapeutic doxorubicin (CS‐DOX‐NCs) for light‐driven synergistic cancer therapy are introduced. CS‐DOX‐NCs possess a J‐type aggregation conformation of cyanine dye within the nanochannels and encapsulate doxorubicin through the π–π interaction with cyanine dye. Under near‐infrared light irradiation, CS‐DOX‐NCs produce the enhanced photothermal conversion efficiency through the maximized nonradiative transition of J‐type Cypate aggregates, trigger the light‐driven drug release through the destabilization of temperature‐sensitive π–π interaction, and generate the effective intracellular translocation of doxorubicin from the lysosomes to cytoplasma through reactive oxygen species‐mediated lysosomal disruption, thereby causing the potent in vivo hyperthermia and intracellular trafficking of drug into cytoplasma at tumors. Moreover, CS‐DOX‐NCs possess good resistance to photobleaching and preferable tumor accumulation, facilitating severe photoinduced cell damage, and subsequent synergy between photothermal and chemotherapeutic therapy with tumor ablation. These findings provide new insights of light‐driven nanoparticles for synergistic cancer therapy.     

Overcoming Non-Specific Interactions for Efficient Encapsulation of Doxorubicin in Ferritin Nanocages for Targeted Drug Delivery

Due to its beneficial pharmacological properties, ferritin (Ftn) is considered as an interesting drug delivery vehicle to alleviate the cardiotoxicity of doxorubicin (DOX) in chemotherapy. However, the encapsulation of DOX in Ftn suffers from heavy precipitation and low protein recovery yield which limits its full potential. Here, a new DOX encapsulation strategy by cysteine-maleimide conjugation is proposed. In order to demonstrate that this strategy is more efficient compared to the other approaches, DOX is encapsulated in Ftn variants carrying different surface charges. Furthermore, in contrast to the common belief, this data show that DOX molecules are also found to bind non-specifically to the surface of Ftn. This can be circumvented by the use of Tris(2-carboxyethyl)phosphine (TCEP) during encapsulation or by washing with acidic buffer. The biocompatibility studies of the resulting DOX Ftn variants in MCF-7 and MHS cancer cells shows a complex relationship between the cytotoxicity, the DOX loading and the different surface charges of Ftn. Further investigation on the cell uptake mechanism provides reasonable explanations for the cytotoxicity results and reveals that surface charging of Ftn hinders its transferrin receptor 1 (TfR-1) mediated cellular uptake in MCF-7 cells.     

A Eutectic Mixture of Natural Fatty Acids Can Serve as the Gating Material for Near‐Infrared‐Triggered Drug Release

A smart release system responsive to near‐infrared (NIR) light is developed for intracellular drug delivery. The concept is demonstrated by coencapsulating doxorubicin (DOX) (an anticancer drug) and IR780 iodide (IR780) (an NIR‐absorbing dye) into nanoparticles made of a eutectic mixture of naturally occurring fatty acids. The eutectic mixture has a well‐defined melting point at 39 °C, and can be used as a biocompatible phase‐change material for NIR‐triggered drug release. The resultant nanoparticles exhibit prominent photothermal effect and quick drug release in response to NIR irradiation. Fluorescence microscopy analysis indicates that the DOX trapped in the nanoparticles can be efficiently released into the cytosol under NIR irradiation, resulting in enhanced anticancer activity. A new platform is thus offered for designing effective intracellular drug‐release systems, holding great promise for future cancer therapy.     

Smart Nanovehicles Based on pH‐Triggered Disassembly of Supramolecular Peptide‐Amphiphiles for Efficient Intracellular Drug Delivery

A novel type of nanovehicle (NV) based on stimuli‐responsive supramolecular peptide‐amphiphiles (SPAs, dendritic poly (L‐lysine) non‐covalently linked poly (L‐leucine)) is developed for intracellular drug delivery. To determine the pH‐dependent mechanism, the supramolecular peptide‐amphiphile system (SPAS) is investigated at different pH conditions using a variety of physical and chemical approaches. The pH‐triggered disassembly of SPAS can be attributed to the disappearance of non‐covalent interactions within SPAs around the isoelectric point of poly (L‐leucine). SPAS is found to encapsulate guest molecules at pH 7.4 but release them at pH 6.2. In this way, SPAS is able to act as a smart NV to deliver its target to tumor cells using intracellular pH as a trigger. The DOX‐loaded NVs are approximately 150 nm in size. In vitro release profiles and confocal laser scanning microscopy (CLSM) images of HepG2 cells confirm that lower pH conditions can trigger the disassembly of NVs and so achieve pH‐dependent intracellular DOX delivery. In vitro cytotoxicity of the DOX‐loaded NVs to HepG2 cells demonstrate that the smart NVs enhance the efficacy of hydrophobic DOX. Fluorescence‐activated cell sorting (FACS) and CLSM results show that the NVs can enhance the endocytosis of DOX into HepG2 cells considerably and deliver DOX to the nuclei.     

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.     

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.     

Amino Acid Metabolism Abnormity and Microenvironment Variation Mediated Targeting and Controlled Glioma Chemotherapy

Energy metabolism abnormity is one of the most significant hallmarks of cancer. As a result, large amino acid transporter 1 (LAT1) is remarkably overexpressed in both blood‐brain‐barrier and glioma tumor cells, leading a rapid and sufficient substrate transportation. 3CDIT and 4CDIT are originally synthesized by modifying the existing most potent LAT1 substrate. 3CDIT is selected as its higher glioma‐targeting ability. Since the microenvironment variation in tumor cells is another important feature of cancer, a great disparity in adenosine‐5′‐triphosphate (ATP) and glutathione (GSH) levels between extracellular and intracellular milieu can provide good possibilities for dual‐responsive drug release in tumor cells. Doxorubicin (DOX) is successfully intercalated into the ATP aptamer DNA scaffolds, compressed by GSH‐responsive polymer pOEI, and modified with 3CDIT to obtain 3CDIT‐targeting pOEI/DOX/ATP aptamer nanoparticles (NPs). Enhanced NP accumulation and rapid GSH & ATP dual‐responsive DOX release in glioma are demonstrated both in vitro and in vivo. More efficient therapeutic effects are shown with 3CDIT‐targeting pOEI/DOX/ATP aptamer NPs than free DOX and no systemic toxicity is observed. Therefore, glioma‐targeting delivery and GSH & ATP dual‐responsive release guarantee an adequate DOX accumulation within tumor cells and ensure a safe and efficient chemotherapy for glioma.     

In vitro evaluation of a novel pH sensitive drug delivery system based cockle shell-derived aragonite nanoparticles against osteosarcoma

ABSTRACT

Background: Osteosarcoma (OS) is a highly malignant primary bone cancer. Severe side effects and multidrug resistance are obstacles faced with chemotherapy against OS. With the hope to overcome the obstacles of the conventional chemotherapy, various targeted drug delivery systems using nanotechnology have been explored in the past few decades. Biogenic calcium carbonate (CaCO₃) has great potential to be a smart drug delivery system.

Results: In this study, cockle shells-derived aragonite nanoparticles (ANPs) were developed and loaded with doxorubicin (DOX). The physicochemical properties of the DOX-loaded ANPs (DOX-ANPs) were characterised by various techniques. The results of drug-loading study demonstrated that DOX was loaded onto ANPs at high loading and encapsulation efficiency (11.09% and 99.58%, respectively). The pH-sensitive release of DOX from DOX-ANPs was successful. At lower pH values (4.8), the release of DOX was much quicker than that at pH 7.4. Additionally, cellular uptake study using fluorescence microscopy showed obviously cellular uptake of DOX-ANPs through endocytosis. Moreover, the flow cytometric analysis revealed DOX-ANPs-induced cell cycle arrest, which was consistent with the mechanism of DOX. DOX-ANPs also showed an efficient cytotoxicity against OS cancer cells, close to the toxicity effect of free DOX at the same concentration. Morphological observations showed microvilli disappearance, chromatin condensation, cell shrinkage, membrane blebbing, and formation of apoptotic bodies, which confirmed both DOX-ANPs- and DOX-induced apoptosis of OS cancer cells in vitro.

Conclusion: Our findings indicated that ANPs could act as a pH-sensitive drug delivery against OS.