Jueun Jeon

Bioreducible core-crosslinked hyaluronic acid micelle for targeted cancer therapy.

For drug delivery nanocarriers to be a safe and effective therapeutic option, blood stability, tumor-targetability, and intracellular drug release features should be considered. In this study, to develop a potent drug delivery carrier that can meet the multiple requirements, we engineered a bioreducible core-crosslinked polymeric micelle based on hyaluronic acid (CC-HAM) by a facile method using d,l-dithiothreitol in aqueous conditions. The CC-HAM exhibited enhanced structural stability under diluted conditions with PBS containing FBS or sodium dodecyl sulfates. We also successfully encapsulated doxorubicin (DOX), chosen as a hydrophobic anti-cancer drug, in CC-HAMs with high loading efficiency (>80%). The drug release rate of CC-HAMs was rapidly accelerated in the presence of glutathione, whereas the drug release was significantly retarded in physiological buffer (pH7.4). An in vivo biodistribution study demonstrated the superior tumor targetability of CC-HAMs to that of non-crosslinked HAMs, primarily ascribed to robust stability of CC-HAMs in the bloodstream. Notably, these results correspond with the improved pharmacokinetics and tumor accumulation of DOX-loaded CC-HAMs as well as their excellent therapeutic efficacy. Overall, these results suggest that the robust, bioreducible CC-HAM can be applied as a potent doxorubicin delivery carrier for targeted cancer therapy.

Tumor microenvironment-specific nanoparticles activatable by stepwise transformation

In an attempt to develop the tumor-targeted nanocarrier which can surmount major challenges for in vivo application, we prepared tumor microenvironment-specific nanoparticles which can be sequentially activated at the extracellular and intracellular levels of tumor tissue by stepwise transformation. This polymeric nanoparticle has been prepared using an amphiphilic polyethyleneimine derivative with the pH-responsive charge-convertible moiety and the reduction-responsive crosslink. Once reaching the tumor tissue in vivo after systemic administration, the surface charge of this nanoparticle can be converted from negative to positive by recognizing the mildly acidic extracellular matrix of tumor, allowing for the enhanced cellular uptake. After the cellular uptake, the nanoparticle can selectively release the drug at the intracellular level since it has the chemically crosslinked core by the disulfide bond which is cleaved in intracellular reductive environment. The tumor microenvironment-specific nanoparticle shows the high tumor targetability and dramatically improves the antitumor efficacy of the drug.

Carboxymethyl dextran-based hypoxia-responsive nanoparticles for doxorubicin delivery

In an attempt to develop the hypoxia-responsive nanoparticles for cancer therapy, a polymer conjugate, consisting of carboxymethyl dextran (CMD) and black hole quencher 3 (BHQ3), was prepared. The polymer conjugate can self-assemble into nanoparticles (CMD-BHQ3 NPs) under aqueous conditions. The anticancer drug, doxorubicin (DOX), was loaded in CMD-BHQ3 NPs to prepare DOX@CMD-BHQ3 NPs. The CMD-BHQ3 NPs released DOX in a sustained manner under physiological conditions, whereas the release rate of DOX remarkably increased under hypoxic conditions throughout the cleavage of the azo bond in BHQ3. In vitro cytotoxicity study revealed that DOX@CMD-BHQ3 NPs showed higher toxicity under hypoxic conditions than normoxic conditions. Confocal microscopic images indicated oxygen-dependent intracellular release of DOX from DOX@CMD-BHQ3. In vivo biodistribution study demonstrated that CMD-BHQ3 NPs were preferentially accumulated in the tumor after systemic administration into tumor-bearing mice. Overall, CMD-BHQ3 might be a promising carrier for selective drug release in the hypoxic tumor.

Gold-stabilized carboxymethyl dextran nanoparticles for image-guided photodynamic therapy of cancer

Photodynamic therapy (PDT) has been extensively investigated to treat cancer since it induces cell death through the activation of photosensitizers by light. However, its success has been hampered by the insufficient selectivity of photosensitizers to tumor tissues. In an attempt to increase the therapeutic efficacy of PDT by targeting the photosensitizer specifically to the tumor site, we prepared chlorin e6 (Ce6)-loaded gold-stabilized carboxymethyl dextran nanoparticles (Ce6-GS-CNPs). Ce6-GS-CNPs possessed highly stable nanostructures and no significant change was observed in their particle size in the presence of serum for 6 days. When Ce6-GS-CNPs were intravenously injected into tumor-bearing mice, they exhibited prolonged circulation in the body and gradually accumulated in the tumor tissue. Under laser irradiation of the tumor site which could be recognized by the near-infrared fluorescence imaging system, Ce6-GS-CNPs effectively suppressed tumor growth. Overall, Ce6-GS-CNPs might have potential as nanomedicine for image-guided photodynamic cancer therapy.

Gold-installed biostable nanocomplexes for tumor-targeted siRNA delivery in vivo.

The key issues, associated with nanocarriers for small interfering RNAs (siRNAs), are their poor stability and lack of tumor targetability in vivo. To address these issues, we developed gold-installed polyethyleneimine/siRNA complexes with a corona of PEGylated hyaluronic acid.

Anti-Trop2 antibody-conjugated bioreducible nanoparticles for targeted triple negative breast cancer therapy

Trop2, a transmembrane glycoprotein, has emerged as a biomarker for targeted cancer therapy since it is overexpressed in 80% of triple negative breast cancer (TNBC) patients. For the site-specific delivery of the anticancer drug into TNBC, anti-Trop2 antibody-conjugated nanoparticles (ST-NPs) were prepared as the potential nanocarrier, composed of carboxymethyl dextran (CMD) derivatives with bioreducible disulfide bonds. Owing to its amphiphilicity, the CMD derivatives were self-assembled into nano-sized particles in an aqueous condition. Doxorubicin (DOX), chosen as a model anticancer drug, was effectively encapsulated into the nanoparticles. DOX-loaded ST-NPs (DOX-ST-NPs) rapidly released DOX in the presence of 10mM glutathione (GSH), whereas the DOX release is significantly retarded in the physiological condition (PBS, pH 7.4). Confocal microscopic images and flow cytometry analysis demonstrated that DOX-ST-NPs were selectively taken up by MDA-MB-231 as the representative Trop2-expressing TNBC cells. Consequently, DOX-ST-NPs exhibited higher toxicity to Trop2-positive MDA-MB-231 cancer cells, compared to DOX-loaded control nanoparticles without the disulfide bond or anti-Trop2 antibody. Overall, ST-NPs might be a promising carrier of DOX for targeted TNBC therapy.

Hypoxia-Responsive Mesoporous Nanoparticles for Doxorubicin Delivery

Hypoxia, or low oxygen tension, is a common feature of solid tumors. Here, we report hypoxia-responsive mesoporous silica nanoparticles (HR-MSNs) with a 4-nitroimidazole-β-cyclodextrin (NI-CD) complex that is acting as the hypoxia-responsive gatekeeper. When these CD-HR-MSNs encountered a hypoxic environment, the nitroimidazole (NI) gatekeeper portion of CD-HR-MSNs disintegrated through bioreduction of the hydrophobic NI state to the hydrophilic NI state. Under hypoxic conditions, the release rate of doxorubicin (DOX) from DOX-loaded CD-HR-MSNs (DOX-CD-HR-MSNs) increased along with the disintegration of the gatekeeper. Conversely, DOX release was retarded under normoxic conditions. In vitro experiments confirmed that DOX-CD-HR-MSNs exhibit higher toxicity to hypoxic cells when compared to normoxic cells. Confocal microscopy images indicated that DOX-CD-HR-MSNs effectively release DOX into SCC-7 cells under hypoxic conditions. These results demonstrate that CD-HR-MSNs can release drugs in a hypoxia-responsive manner, and thus are promising drug carriers for hypoxia-targeted cancer therapy.

Ultrasmall gold nanosatellite-bearing transformable hybrid nanoparticles for deep tumor penetration

Since delivering drugs to an entire tumoral region leads to high therapeutic efficacy and good prognosis, achieving deep tumoral penetration of drugs is a major issue in cancer treatment. In this regard, conventional nanomedicines (>50 nm) have shown limitations in cancer therapy, primarily attributed to the heterogeneous distribution of drugs because of the physiological barrier of the tumor interstitial space. To address this issue, we prepared transformable hybrid nanoparticles (TNPs) consisting of a pH-responsive nanocarrier (PEG-PBAE) and doxorubicin (DOX)-conjugated ultrasmall (<3 nm) gold nanoparticles (nanosatellites). It has been shown that PEG-PBAE can serve as a reservoir for nanosatellites and release them in mildly acidic conditions (pH 6.5), mimicking the tumor microenvironment. When DOX-loaded TNPs (DOX-TNPs) were intravenously injected into tumor-bearing mice, they successfully accumulated and dissociated at the extracellular level of the tumor, leading to the disclosure of nanosatellites and free DOX. While the free DOX accumulated in tumor tissue near blood vessels, the deeply diffused nanosatellites were taken up by the tumor cell, followed by the release of DOX via cleavage of pH-responsive ester linkages in the nanosatellites at the intracellular level. Consequently, the DOX-TNPs effectively suppressed tumor growth through improved tumor penetration of DOX, suggesting their promising potential as a cancer nanomedicine. STATEMENT OF SIGNIFICANCE Deep tumor penetration of anticancer drug is an important issue for high therapeutic efficacy. If the drugs cannot reach cancer cells in a sufficient concentration, their effectiveness will be limited. In this regard, conventional nanomedicine showed only modest therapeutic efficacy since they cannot deliver their payloads to the deep site of tumor tissue. This heterogeneous distribution of the drug is primarily attributed to the physiological barriers of the tumor microenvironment, including a dense extracellular matrix. To surmount this challenge, we developed tumor acidity-triggered transformable nanoparticles. By encapsulating doxorubicin-conjugated ultrasmall gold nanosatellites into the nanoparticles, the drug was not significantly bound to genetic materials, resulting in its minimal sequestration near the vasculature and deep tumor penetration. Our strategy could resolve not only the poor penetration issue of the drug but also its restricted tumor accumulation, suggesting the potential as an effective nanotherapeutics.