Dual Targeted Nanoparticles for the Codelivery of Doxorubicin and siRNA Cocktails to Overcome Ovarian Cancer Stem Cells.

Most anticancer treatments only induce the death of ordinary cancer cells, while cancer stem cells (CSCs) in the quiescent phase of cell division are difficult to kill, which eventually leads to cancer drug resistance, metastasis, and relapse. Therefore, CSCs are also important in targeted cancer therapy. Herein, we developed dual-targeted and glutathione (GSH)-responsive novel nanoparticles (SSBPEI-DOX@siRNAs/iRGD-PEG-HA) to efficiently and specifically deliver both doxorubicin and small interfering RNA cocktails (siRNAs) (survivin siRNA, Bcl-2 siRNA and ABCG2 siRNA) to ovarian CSCs. They are fabricated via electrostatic assembly of anionic siRNAs and cationic disulfide bond crosslinking-branched polyethyleneimine-doxorubicin (SSBPEI-DOX) as a core. Interestingly, the SSBPEI-DOX could be degraded into low-cytotoxic polyethyleneimine (PEI). Because of the enrichment of glutathione reductase in the tumor microenvironment, the disulfide bond (-SS-) in SSBPEI-DOX can be specifically reduced to promote the controlled release of siRNA and doxorubicin (DOX) in the CSCs. siRNA cocktails could specifically silence three key genes in CSCs, which, in combination with the traditional chemotherapy drug DOX, induces apoptosis or necrosis of CSCs. iRGD peptides and "sheddable" hyaluronic acid (HA) wrapped around the core could mediate CSC targeting by binding with neuropilin-1 (NRP1) and CD44 to enhance delivery. In summary, the multifunctional delivery system SSBPEI-DOX@siRNAs/iRGD-PEG-HA nanoparticles displays excellent biocompatibility, accurate CSC-targeting ability, and powerful anti-CSC ability, which demonstrates its potential value in future treatments to overcome ovarian cancer metastasis and relapse. To support this work, as exhaustive search was conducted for the literature on nanoparticle drug delivery research conducted in the last 17 years (2007-2023) using PubMed, Web of Science, and Google Scholar.

Reduction sensitive nanocarriers mPEG-g-γ-PGA/SSBPEI@siRNA for effective targeted delivery of survivin siRNA against NSCLC.

Poly γ-glutamic acid (γ-PGA) is attractive due to its desirable biological properties such as nontoxicity, excellent biocompatibility, and minimal immunogenicity. Additionally, γ-PGA could be recognized by γ-glutamyl transpeptidase, which is regarded as a potential biomarker for many tumors. In this study, we have developed a new biodegradable, reduction sensitive, and tumor-specific gene nano-delivery platform consisting of a cationic carrier (SSBPEI) for siRNA condensation, mPEG shell for nanoparticle stabilization, and γ-PGA for accelerated cellular uptake. Disulfide bonds (-SS-) could be reduced specifically in the tumor environment, which is full of reductants such as glutathione reductase. Conjugating polyethylene glycol (PEG) to the γ-PGA led to the formation of mPEG-g-γ-PGA, with a decreased positive charge on the surface of SSBPEI@siRNA and substantially higher stability in an aqueous medium. As a result, mPEG-g-γ-PGA/SSBPEI@siRNA nanoparticles could protect siRNAs from RNase A degradation and release siRNAs in a reduction sensitive way. The multifunctional delivery system was shown to silence the Survivin gene and further promote chemotherapeutic drug-induced apoptosis in the A549 NSCLC cell line efficiently, thereby representing a novel promising platform for the delivery of siRNAs.

Reduction sensitive CC9-PEG-SSBPEI/miR-148b nanoparticles: Synthesis, characterization, targeting delivery and application for anti-metastasis.

miRNAs such as miR-148b play crucial regulatory role in tumor metastasis, but their applications are limited because they are easy to degrade in serum conditions and lack targeting ability. Herein, CC9-PEG-SSBPEI was synthesized and used as nano-carrier for miR-148b. DLS and gel retardation analyses indicated that CC9-PEG-SSBPEI could combine with miR-148b by charge interaction and formed into nanoparticles with the size changed from 811.6 nm to 146.4 nm. CC9-PEG-SSBPEI could protect miR-148b from RNase A degradation and showed a reduction sensitive release of miR-148b. FACS analysis and CLSM images displayed that the conjugated CC9 peptide improved the accumulation and penetration of the nanoparticles in HuH-7 liver cancer cells through binding with the target of miR-148b neuropilin-1(NRP-1) on the cell surface. The raised level of miR-148b in turn inhibited the expression of NRP-1 and suppressed the migration of HuH-7 liver cancer cells. Moreover, hemolysis and cytotoxicity assay demonstrated that the nanoparticles had good hemo- and cyto- compatibility. Hence, CC9-PEG-SSBPEI/miR-148b nanoparticles had the potential for targeting delivery of miR-148b and anti-metastasis of hepatocellular carcinoma (HCC) cells.

Preparation for nitrocellulose membrane-poly (vinyl alcohol)-ionic imprinting and its application to determine trace copper by room temperature phosphorimetry.

Nitrocellulose membrane-poly (vinyl alcohol)-ionic imprinting (NCM-PVA-I-I) was prepared using Cu2+ as template. The cavity in NCM-PVA-I-I matched Cu2+ very well and the selectivity was high. Cu2+ entered the cavity and then could form ionic association ([Cu2+] x [(Fin-)2]) with the anion of fluorescein (Fin-) outside the cavity by electrostatic effect. [Cu2+] x [(Fin-)2] could emit strong and stable room temperature phosphorescence on NCM-PVA-I-I. Its DeltaI(p) was proportional to the content of Cu2+. Based on the above facts, a new method for the determination of trace copper by solid substrate-room temperature phosphorimetry (NCM-PVA-I-I-SS-RTP, SS-RTP is the abbreviation of solid substrate-room temperature phosphorimetry) using NCM-PVA-I-I technique has been established. The linear range of this method was 2.00-144.00 fg Cu2+ spot(-1) (sample volume: 0.40 microL spot(-1), corresponding concentration: 5.00-360.00 pg mL(-1)), and the detection limit calculated by 3Sb/k was 0.43 fg Cu2+ spot(-1) (corresponding concentration: 1.1 x 10(-12) g mL(-1), n=11). Samples containing 2.00 and 144.00 fg Cu2+spot(-1) were measured, respectively, for seven times and R.S.D.s were 3.5% and 4.7%. NCM-PVA-I-I-SS-RTP could combine very well the characteristics of both the high sensitivity of SS-RTP and the high match and selectivity of NCM-PVA-I-I, and it was rapid, accurate, sensitive and with good repeatability. It has been successfully applied to determine trace copper in human hair and tea samples.