Delivery System For Cancer Therapy Research Articles

A stimulus responsive microneedle-based drug delivery system for cancer therapy.

The intricate nature of the tumor microenvironment (TME) results in the inefficient delivery of anticancer drugs within tumor tissues, significantly compromising the therapeutic effect of cancer treatment. To address this issue, transdermal drug delivery microneedles (MNs) with high mechanical strength have emerged. Such MNs penetrate the skin barrier, enabling efficient drug delivery to tumor tissues. This approach enhances drug bioavailability, while also mitigating concerns such as liver and kidney toxicity associated with intravenous and oral drug administration. Notably, stimulus responsive MNs designed for drug delivery have the capacity to respond to various biological signals and pathological changes. This adaptability enables them to exert therapeutic effects within the TME, exploiting biochemical variations and tailoring treatment strategies to suit tumor characteristics. The present review surveys recent advancements in responsive MN systems. This comprehensive analysis serves as a valuable reference for the prospective application of smart MN drug delivery systems in cancer therapy.

A biocompatible drug controlled release system based on β-cyclodextrin crosslinked magnetic lactose/ZIF-8 metal-organic frameworks for cancer treatment

Natural saccharides (Chitosan, Lactose, alginate, and β-cyclodextrin) have recently attracted much attention from researchers as drug delivery systems for cancer therapy. In this regard, for the first time, we designed a new targeted carrier based on magnetic lactose-modified ZIF-8 metal-organic frameworks crosslinked with β-cyclodextrin (M-Lactose@ZIF-8-β-CD) for the pH-responsive controlled release of anticancer drugs, hydrophilic doxorubicin (DOX), and hydrophobic curcumin (CUR) to MCF-7 breast cancer cells. The encapsulation efficiency of M-Lactose@ZIF-8-β-CD was found to be 95.16% for DOX and 65.01% for CUR. The in vitro release studies showed a pH-responsive controlled release of DOX and CUR from M-Lactose@ZIF-8-β-CD at pH 5, which confirmed the performance of the prepared carrier in the cancerous microenvironments. The release mechanism of both drugs was well described by the Korsmeyer-Peppas and Fickian diffusion. In addition, in vitro cytotoxicity, hemolysis, and antioxidant investigations clearly showed that the prepared M-Lactose@ZIF-8-β-CD carriers had good biocompatibility, high blood compatibility, and excellent antioxidant activity due to the presence of natural saccharides in carriers. Based on these findings, the M-Lactose@ZIF-8-β-CD can be applied as a promising targeted co-drug delivery carrier for cancer therapy.

A biodegradable lipid nanoparticle delivers a Cas9 ribonucleoprotein for efficient and safe in situ genome editing in melanoma

The development of melanoma is closely related to Braf gene, which is a suitable target for CRISPR/Cas9 based gene therapy. CRISPR/Cas9-sgRNA ribonucleoprotein complexes (RNPs) stand out as the safest format compared to plasmid and mRNA delivery. Similarly, lipid nanoparticles (LNPs) emerge as a safer alternative to viral vectors for delivering the CRISPR/Cas9-sgRNA gene editing system. Herein, we have designed multifunctional cationic LNPs specifically tailored for the efficient delivery of Cas9 RNPs targeting the mouse Braf gene through transdermal delivery, aiming to treat mouse melanoma. LNPs are given a positive charge by the addition of a newly synthesized polymer, deoxycholic acid modified polyethyleneimine (PEI-DOCA). Positive charge enables LNPs to be delivered in vivo by binding to negatively charged cell membranes and proteins, thereby facilitating efficient skin penetration and enhancing the delivery of RNPs into melanoma cells for gene editing purposes. Our research demonstrates that these LNPs enhance drug penetration through the skin, successfully delivering the Cas9 RNPs system and specifically targeting the Braf gene. Cas9 RNPs loaded LNPs exert a notable impact on gene editing in melanoma cells, significantly suppressing their proliferation. Furthermore, in mice experiments, the LNPs exhibited skin penetration and tumor targeting capabilities. This innovative LNPs delivery system offers a promising gene therapy approach for melanoma treatment and provides fresh insights into the development of safe and effective delivery systems for Cas9 RNPs in vivo. Statement of significanceCRISPR/Cas9 technology brings new hope for cancer treatment. Cas9 ribonucleoprotein offers direct genome editing, yet delivery challenges persist. For melanoma, transdermal delivery minimizes toxicity but faces skin barrier issues. We designed multifunctional lipid nanoparticles (LNPs) for Cas9 RNP delivery targeting the Braf gene. With metal microneedle pretreatment, our LNPs effectively edited melanoma cells, reducing Braf expression and inhibiting tumor growth. Our study demonstrates LNPs' potential for melanoma therapy and paves the way for efficient in vivo Cas9 RNP delivery systems in cancer therapy.

Temperature switchable linkers suitable for triggered drug release in cancer thermo-chemotherapy

In drug delivery systems, a stimuli-responsive linker that attaches a targeting carrier and a cytotoxic payload can be dissociated to release the payload on the target over the action of a stimuli, thereby it would harden the selectivity, specificity and potency of the cytotoxic agent against targeted tissues whilst sparing the drug-induced toxicity on normal cells. Oligonucleotide duplexes can unwind and be separated into single-stranded random coils under a defined temperature, and this property makes the oligonucleotide an appealing thermo-responsive linker. In this work, we studied the melting temperatures of different DNA linkers with various lengths and mismatches inserted in the double helix with either different numbers or positions. We further chose the DNA linkers that can unwind at the hyperthermia temperature and used them in the construction of four different drug delivery systems both in vitro and in vivo. Results showed that the chosen DNA linkers in all of the constructed delivery systems can successfully unwind and release cargos or drugs after application of heat compared to control groups. This research demonstrated the potential applications of DNA duplexes as temperature-sensitive linkers of drug delivery systems for cancer therapy.

Exploring the potential of nanoparticles as a drug delivery system for cancer therapy: A review

In this review, we discuss the use of organic nanoparticles such as liposomes, polymeric nanoparticles, dendrimers, and inorganic nanoparticles such as gold nanoparticles and mesoporous silica nanoparticles in drug delivery in chemotherapy for cancer therapy. Another strategy is the use of nanoparticle vehicles for drug delivery through the natural openings on tumor vessels called fenestrations. Both of these can be functionalized to attach angiotensin to lymphocytes or any certain part of the cancer cell membrane, microenvironment, or cytoplasmic or nuclear receptor sites, and therefore a high concentration of drug delivery to targeted cancer cells is achieved, but with less or no toxicity to normal tissue. The potential advantages evident in this technology are useful approaches to established high-concentration drug treatment of cancer tissues without harming normal cells. Some features of a nanoparticle-based drug delivery system include the durability of the vehicle, biocompatibility, permeation, and ability to target specific types of cells. Organic and inorganic nanoparticles have developed this kind of drug-carrier system. Particulate systems are also still being explored for cancer drug resistance mechanisms, and their function in immunotherapy is expanding.

Development and evaluation of biodegradable alginate beads loaded with sorafenib for cancer treatment

The study focused on fabricating and characterizing sorafenib-loaded calcium alginate beads for potential cancer therapy application. The beads were synthesized via ionotropic gelation using calcium chloride as a crosslinker. Successful sorafenib encapsulation was confirmed through various analytical techniques, including FTIR, XRD, SEM, and UV-Vis spectroscopy. FTIR analysis showed shifts in characteristic bands, indicating effective drug loading. XRD patterns revealed both amorphous and crystalline characteristics, with peaks corresponding to the drug and polymer. SEM images depicted spherical beads with surface roughness. UV-Vis spectrum analysis demonstrated high encapsulation efficiencies ranging from 99.48 % to 99.82 %, depending on the sorafenib concentration. Biodegradation studies suggested the beads' potential for drug delivery, showing gradual weight and shape loss. Antioxidant assays indicated superior scavenging activity, while antibacterial assays showed good activity against Bacillus species. Cytotoxicity studies revealed specific toxicity against MCF7 breast cancer cells. Drug release data fitted well with the first-order model, indicating controlled release properties. These findings highlight the potential of sorafenib-loaded calcium alginate beads as an effective delivery system for cancer therapy.

Applications of Tissue Engineering

This article is written from a beginner's perspective to elucidate the concept of tissue engineering through its applications. It elaborates on the role of tissue engineering in burn skin treatment and drug delivery systems for cancer therapy. The first part of this article discusses the challenges and current issues related to burn injuries and the engineered techniques for their treatment. It highlights the need for scaffolds in skin tissue regeneration, along with the materials and methods used for treatment. The second part focuses on drug delivery mechanisms in tissue engineering, specifically in cancer treatments, explaining the carrier and release mechanisms of drugs targeting cancer cells. Most information was gathered from scientific articles, following the selection of focused applications. The basics of these applications were studied and explained in layman's terms, forming the foundation for an application-based learning experience. Personal reflections and comments are synthesized in the conclusion, making it accessible for those who want to learn about tissue engineering at a glance.

Extracellular Vesicles as Drug Delivery System for Cancer Therapy.

In recent decades, the pursuit of drug delivery systems has led to the development of numerous synthetic options aimed at enhancing drug efficacy while minimizing side effects. However, the practical application of these systems is often hindered by challenges such as inefficiency, cytotoxicity, and immunogenicity. Extracellular vesicles, natural carriers for drugs, emerge as promising alternatives with distinct advantages over synthetic carriers. Notably, EVs exhibit biocompatibility, low immunogenicity, and inherent tissue-targeting capabilities, thus opening new avenues for drug delivery strategies. This review provides an overview of EVs, including their biogenesis and absorption mechanisms. Additionally, we explore the current research efforts focusing on harnessing their potential as drug carriers, encompassing aspects such as purification techniques, drug loading, and bioengineering for targeted delivery. Finally, we discuss the existing challenges and future prospects of EVs as therapeutic agents in clinical settings. This comprehensive analysis aims to shed light on the potential of EVs as versatile and effective tools for drug delivery, particularly in the realm of cancer therapy.

Advances in Light-Responsive Smart Multifunctional Nanofibers: Implications for Targeted Drug Delivery and Cancer Therapy.

Over the last decade, scientists have shifted their focus to the development of smart carriers for the delivery of chemotherapeutics in order to overcome the problems associated with traditional chemotherapy, such as poor aqueous solubility and bioavailability, low selectivity and targeting specificity, off-target drug side effects, and damage to surrounding healthy tissues. Nanofiber-based drug delivery systems have recently emerged as a promising drug delivery system in cancer therapy owing to their unique structural and functional properties, including tunable interconnected porosity, a high surface-to-volume ratio associated with high entrapment efficiency and drug loading capacity, and high mass transport properties, which allow for controlled and targeted drug delivery. In addition, they are biocompatible, biodegradable, and capable of surface functionalization, allowing for target-specific delivery and drug release. One of the most common fiber production methods is electrospinning, even though the relatively two-dimensional (2D) tightly packed fiber structures and low production rates have limited its performance. Forcespinning is an alternative spinning technology that generates high-throughput, continuous polymeric nanofibers with 3D structures. Unlike electrospinning, forcespinning generates fibers by centrifugal forces rather than electrostatic forces, resulting in significantly higher fiber production. The functionalization of nanocarriers on nanofibers can result in smart nanofibers with anticancer capabilities that can be activated by external stimuli, such as light. This review addresses current trends and potential applications of light-responsive and dual-stimuli-responsive electro- and forcespun smart nanofibers in cancer therapy, with a particular emphasis on functionalizing nanofiber surfaces and developing nano-in-nanofiber emerging delivery systems for dual-controlled drug release and high-precision tumor targeting. In addition, the progress and prospective diagnostic and therapeutic applications of light-responsive and dual-stimuli-responsive smart nanofibers are discussed in the context of combination cancer therapy.

Reduction-Responsive Polyprodrug Nanoplatform Based on Curcumin for Tumor-Targeted Therapy.

Polymer prodrug nanoparticles have become an emerging drug delivery system in cancer therapy due to their high drug loading. However, their poor drug release and lack of tumor cell targeting limit their clinical application. This study aimed to prepare targeted and reduction-reactive polyprodrug nanocarriers based on curcumin (CUR) for co-delivery of doxorubicin (DOX), labeled as DOX/HAPCS NPs, and to investigate their anticancer activity. The polymer was synthesized and characterized by chemical method. The drug loading and drug release behavior of DOX and CUR in polymer nanoparticles were determined. Moreover, the antitumor effects of polymer nanoparticles were evaluated using an MTT experiment and tumor inhibition experiment, and the synergistic effect of co-delivered DOX and CUR was explored. The particle size of DOX/HAPCS NPs was 152.5nm, and the potential was about -26.74 mV. The drug-carrying capacity of DOX and CUR was about 7.56% and 34.75%, respectively, indicating high drug-carrying capacity and good stability. DOX and CUR released over 90% within 24 hours in the tumor environment. Compared with free DOX, DOX/HAPCS NPs demonstrated significantly enhanced cell and tumor inhibitory effects (P< 0.05) in vivo and in vitro and changed drug distribution to avoid toxic side effects on normal tissues. The combined index showed that DOX and CUR showed synergistic anticancer effects at a set ratio. The prepared reduction-responsive targeted polymer nanomedical DOX/HAPCS NPs exhibited a synergistic anti-cancer effect, with high drug loading capacity and the ability to release drugs in proportion, making it a promising polymer nanoparticle drug delivery system.

Platelet-Drug Conjugates Engineered via One-step Fusion Approach for Metastatic and Postoperative Cancer Treatment.

The exploration of cell-based drug delivery systems for cancer therapy has gained growing attention. Approaches to engineering therapeutic cells with multidrug loading in an effective, safe, and precise manner while preserving their inherent biological properties remain of great interest. Here, we report a strategy to simultaneously load multiple drugs in platelets in a one-step fusion process. We demonstrate doxorubicin (DOX)-encapsulated liposomes conjugated with interleukin-15 (IL-15) could fuse with platelets to achieve both cytoplasmic drug loading and surface cytokine modification with a loading efficiency of over 70 % within minutes. Due to their inherent targeting ability to metastatic cancers and postoperative bleeding sites, the engineered platelets demonstrated a synergistic therapeutic effect to suppress lung metastasis and postoperative recurrence in mouse B16F10 melanoma tumor models.

Platelet‐Drug Conjugates Engineered via One‐step Fusion Approach for Metastatic and Postoperative Cancer Treatment

AbstractThe exploration of cell‐based drug delivery systems for cancer therapy has gained growing attention. Approaches to engineering therapeutic cells with multidrug loading in an effective, safe, and precise manner while preserving their inherent biological properties remain of great interest. Here, we report a strategy to simultaneously load multiple drugs in platelets in a one‐step fusion process. We demonstrate doxorubicin (DOX)‐encapsulated liposomes conjugated with interleukin‐15 (IL‐15) could fuse with platelets to achieve both cytoplasmic drug loading and surface cytokine modification with a loading efficiency of over 70 % within minutes. Due to their inherent targeting ability to metastatic cancers and postoperative bleeding sites, the engineered platelets demonstrated a synergistic therapeutic effect to suppress lung metastasis and postoperative recurrence in mouse B16F10 melanoma tumor models.

Targeted Hybrid Nanocarriers as Co-Delivery Systems for Enhanced Cancer Therapy.

Hybrid nanocarriers have realized a growing interest in drug delivery research because of the potential of being able to treat, manage or cure diseases that previously had limited therapy or cure. Cancer is currently considered the second leading cause of death globally. This makes cancer therapy a major focus in terms of the need for efficacious and safe drug formulations that can be used to reduce the rate of morbidity and mortality globally. The major challenge encountered over the years with cancer chemotherapy is the non-selectivity of anticancer drugs, leading to severe adverse effects in patients. Multidrug resistance has also resulted in treatment failure in cancer chemotherapy over the years. Hybrid nanocarriers can be targeted to the site and offer co-delivery of two or more chemotherapeutics, thus leading to synergistic or additive results. This makes hybrid nanocarriers an extremely attractive type of drug delivery system for cancer therapy. Hybrid nanocarrier systems are also attracting attention as possible non-viral gene vectors that could have a higher level of transfection, and be efficacious, with the added advantage of being safer than viral vectors in clinical settings. An extensive review of various aspects of hybrid nanocarriers was discussed in this paper. It is envisaged that in the future, metastatic cancers, multi-drug resistant cancers, and low prognosis cancers like pancreatic cancers, will have a lasting solution via hybrid nanocarrier formulations with targeted co-delivery of therapeutics.

Glycan-based scaffolds and nanoparticles as drug delivery system in cancer therapy.

Glycan-based scaffolds are unique in their high specificity, versatility, low immunogenicity, and ability to mimic natural carbohydrates, making them attractive candidates for use in cancer treatment. These scaffolds are made up of glycans, which are biopolymers with well biocompatibility in the human body that can be used for drug delivery. The versatility of glycan-based scaffolds allows for the modulation of drug activity and targeted delivery to specific cells or tissues, which increases the potency of drugs and reduces side effects. Despite their promise, there are still technical challenges in the design and production of glycan-based scaffolds, as well as limitations in their therapeutic efficacy and specificity.

Shape Matters: Impact of Mesoporous Silica Nanoparticle Morphology on Anti-Tumor Efficacy.

A nanoparticle's shape is a critical determinant of its biological interactions and therapeutic effectiveness. This study investigates the influence of shape on the performance of mesoporous silica nanoparticles (MSNs) in anticancer therapy. MSNs with spherical, rod-like, and hexagonal-plate-like shapes were synthesized, with particle sizes of around 240 nm, and their other surface properties were characterized. The drug loading capacities of the three shapes were controlled to be 47.46%, 49.41%, and 46.65%, respectively. The effects of shape on the release behaviors, cellular uptake mechanisms, and pharmacological behaviors of MSNs were systematically investigated. Through a series of in vitro studies using 4T1 cells and in vivo evaluations in 4T1 tumor-bearing mice, the release kinetics, cellular behaviors, pharmacological effects, circulation profiles, and therapeutic efficacy of MSNs were comprehensively assessed. Notably, hexagonal-plate-shaped MSNs loaded with PTX exhibited a prolonged circulation time (t1/2 = 13.59 ± 0.96 h), which was approximately 1.3 times that of spherical MSNs (t1/2 = 10.16 ± 0.38 h) and 1.5 times that of rod-shaped MSNs (t1/2 = 8.76 ± 1.37 h). This research underscores the significance of nanoparticles' shapes in dictating their biological interactions and therapeutic outcomes, providing valuable insights for the rational design of targeted drug delivery systems in cancer therapy.

Exploring the potential of silymarin-loaded nanovesicles as an effective drug delivery system for cancer therapy: in vivo, in vitro, and in silico experiments.

We aimed to perform a comprehensive study on the development and characterization of silymarin (Syl)-loaded niosomes as potential drug delivery systems. The results demonstrate significant novelty and promising outcomes in terms of morphology, size distribution, encapsulation efficiency, in vitro release behavior, free energy profiles of Syl across the niosome bilayer, hydrogen bonding interactions, antimicrobial properties, cytotoxicity, and in vivo evaluations. The physical appearance, size, and morphology assessment of free niosomes and Syl-loaded niosomes indicated stable and well-formed vesicular structures suitable for drug delivery. Transmission electron microscopy (TEM) analysis revealed spherical shapes with distinct sizes for each formulation, confirming uniform distribution. Dynamic light scattering (DLS) analysis confirmed the size distribution results with higher polydispersity index for Syl-loaded niosomes. The encapsulation efficiency of Syl in the niosomes was remarkable at approximately 91%, ensuring protection and controlled release of the drug. In vitro release studies showed a sustained release profile for Syl-loaded niosomes, enhancing therapeutic efficacy over time. Free energy profiles analysis identified energy barriers hindering Syl permeation through the niosome bilayer, emphasizing challenges in drug delivery system design. Hydrogen bonding interactions between Syl and niosome components contributed to energy barriers, impacting drug permeability. Antimicrobial assessments revealed significant differences in inhibitory effects against S. aureus and E. coli. Cytotoxicity evaluations demonstrated the superior tumor-killing potential of Syl-loaded niosomes compared to free Syl. In vivo studies indicated niosome formulations' safety profiles in terms of liver and kidney parameters compared to bulk Syl, showcasing potential for clinical applications. Overall, this research highlights the promising potential of Syl-loaded niosomes as effective drug delivery systems with enhanced stability, controlled release, and improved therapeutic outcomes.

Exosomes and Their Application as Drug Delivery System in Cancer Therapy

Exosomes are extracellular vesicles naturally released from cells. Exosomes from different sources play different roles in cellular component exchange, signal transduction, and pathological development. Exosomes have distinct biological characteristics such as low immunogenicity, easy uptake by cells, crossing the blood-brain barrier, natural targeting, and easy modification. Many studies show that exosomes as drug carriers have a great application prospect in cancer therapy. In this review, we review the biogenesis, origin, biological characteristics of exosomes, and the exosome drug delivery system and its application for cancer therapy are summarized to provide a reference for the study of exosomes.

Tumor microenvironment‐responsive hyaluronic acid‐oxaliplatin nanoparticles enhanced tumor cell elimination

AbstractOxaliplatin (OXA) is widely utilized in clinical cancer treatment, however its effectiveness is hindered by drug resistance and severe side effects resulting from non‐targeted delivery and lack of response to the tumor environment. In this research, thiol modified OXA and oligo hyaluronic acid (oHA) were used to developed a redox‐responsive OXA‐SS‐oHA nanoparticle delivery system. The nanoparticles could release oxaliplatin prodrug OXA‐SH through the cleavage of disulfide bonds in response of the abundant GSH in the tumor environment. OXA‐SS‐oHA nanoparticles were stable in aqueous solution for 7 days, and in vitro release experiments showed that the cumulative release of OXA in the absence of GSH was 21%, while in the presence of 10 mM concentration of GSH, the cumulative release was 47%. Additionally, OXA‐SS‐oHA demonstrated greater efficacy in inducing cell death in GSH‐positive cells (MKN45) when compared to GSH‐negative cells (L929). This study provides a novel strategy for the construction of GSH‐stimulated responsive targeted drug delivery systems for cancer therapy.

Development of injectable upconversion nanoparticle-conjugated doxorubicin theranostics electrospun nanostructure for targeted photochemotherapy in breast cancer.

Nanotheranostic-based photochemotherapies with targeted drug delivery have considerably surfaced in cancer therapy. In the presented work, polyethyleneimine-coated upconversion nanoparticles were engineered to conjugate covalently with doxorubicin. Upconversion nanoparticles (UCNP)-Doxorubicin (DOX)/synthesized epidermal growth factor receptor-targeting peptide blended with polymer composite was electrospun and formulated as the injectable dosage form. The size of the UCNP and the nanofiber diameter were assessed as 26.75 ± 1.54 and 162 ± 2.82 nm, respectively. The optimized ratio of dopants resulted in UCNP photoluminescence with maximum emission intensity at around 800 nm upon 980 nm excitation wavelength. The paramagnetic nature of UCNPs and amide conjugation with the drug was confirmed analytically. The loading capacity of UCNP for doxorubicin was determined to be 54.56%, while nanofibers exhibited 98.74% capacity to encapsulate UCNP-DOX. The release profile of UCNP-DOX from nanofiber formulation ranged from sustained to controlled, with relative enhancement in acidic conditions. The nanofiber demonstrated good mechanical strength, robust swelling, and degradation rate. Biocompatibility tests showed more than 90% cell viability on L929 and NIH/3T3 cell lines with UCNP-DOX@NF/pep nanoformulation. The IC50 values of 2.15 ± 0.54, 2.87 ± 0.67, and 3.42 ± 0.45 μg/mL on MDA-MB-231, 4T1, and MCF-7 cancer cell line, respectively, with a significant cellular uptake, has been reported. The UCNP protruded a ≈62.7°C temperature rise within 5 min of 980 nm laser irradiation and a power density of 0.5 W cm-2. The nanoformulation induced reactive oxygen species of 65.67% ± 3.21% and apoptosis by arresting the cell cycle sub-G1 phase. The evaluation conveys the effectiveness of the developed injectable theranostic delivery system in cancer therapy.

PH/GSH-responsive diselenide-containing micelle via backbone ketoxime cross-links for efficient drug delivery and controlled release

Stimulus-responsive polymers are promising drug delivery systems for cancer therapy. However, low drug loading and drug leakage of polymeric carriers remain challenges. Here, a crosslinked diselenide-containing micelle was developed with pH/GSH dual responsiveness. Polyesters with multiple diselenide bonds and pendant ketone groups were synthesized by the ring-opening copolymerization of three cyclic monomers (diselenide-containing macrocyclic carbonate, 2-oxepane-1,5-dione, and 1,3-dioxan-2-one). The crosslinked polyester was obtained by the oxime click reaction of pendant ketone groups with hydroxylamine and then self-assembled into crosslinked micelle. This crosslinked micelle remained stable for 14 days, and responded to disassembly under the condition of pH = 5.0 and 10 mM glutathione (GSH). When the crosslinked micelle was loaded with the chemotherapeutic drug DOX, which possessed an active ketone group, the encapsulation efficiency of the crosslinked micelle increased to 91.36 %. The cumulative DOX release reached approximately 45 % under pH = 5.0 and 10 mM GSH. Importantly, the crosslinked diselenide-containing micelle could be taken up in MCF-7 breast cancer cells, responding to the tumor microenvironment and releasing encapsulated DOX. This crosslinked diselenide-containing micelle with pH/GSH dual responsiveness was proven to be a stable and efficient carrier with a promising application.