Fructose and biotin co-modified liposomes for dual-targeting breast cancer.

Chemotherapy, as the main treatment for breast cancer, inevitably damages normal tissues due to the lack of targeting. Various nano targeting drug delivery systems (TDDS) have the potential to be developed as anticancer therapeutics. Although mono-ligand-directed liposomes have been used with some success, dual-ligand-directed liposomes exhibit promising advantages. In current work, we synthesized a Y-shaped ligand covalently linking fructose and biotin (Fru-Bio-Chol) to prepare a dual-targeting liposome Fru-Bio-Lip for breast cancer. The targeting ability was evaluated by comparing the Fru-Bio-Lip with the non-modified liposome (Lip), fructose or biotin mono modified liposomes (Fru-Lip and Bio-Lip), and another dual-targeting liposome (Fru + Bio-Lip) physically mixing fructose and biotin mono modified ligands (Fru-Chol and Bio-Chol). The cellular uptake of Fru-Bio-Lip is 3.27-, 1.81-, 2.19-, 1.15-times that of Lip, Fru-Lip, Bio-Lip and Fru + Bio-Lip on 4T1 cells, and 3.11-, 1.80-, 1.89-, 1.15-times on MCF-7 cells. Additionally, the uptake mechanism indicates the uptake of Fru-Bio-Lip is energy-dependently achieved through multiple endocytosis pathway with a dual recognition of fructose and biotin by GLUT5 and SMVT. The cytotoxicity and apoptosis assay show PTX-Fru-Bio-Lip among liposomes have the strongest proliferation inhibitory effect on breast cancer cells, and the apoptosis rate is 1.7-times that of PTX-Lip. In vivo images indicate Fru-Bio-Lip have the strongest tumour enrichment ability, which is 2.76-, 1.60-, 1.96-, 1.40-times that of Lip, Fru-Lip, Bio-Lip and Fru + Bio-Lip, respectively. Overall, the fructose and biotin covalently modified liposomes improved breast cancer targeting ability, demonstrating great potential as a drug delivery system for breast cancer.

Biotin and glucose dual-targeting, ligand-modified liposomes promote breast tumor-specific drug delivery.

Breast cancer is the second leading cause of cancer-related deaths in women. Ligand-modified liposomes are used for breast tumor-specific drug delivery to improve the efficacy and reduce the side effects of chemotherapy; however, only a few liposomes with high targeting efficiency have been developed because the mono-targeting, ligand-modified liposomes are generally unable to deliver an adequate therapeutic dose. In this study, we designed biotin-glucose branched ligand-modified, dual-targeting liposomes (Bio-Glu-Lip) and evaluated their potential as a targeted chemotherapy delivery system in vitro and in vivo. When compared with the non-targeting liposome (Lip), Bio-Lip, and Glu-Lip, Bio-Glu-Lip had the highest cell uptake in 4T1 cells (3.00-fold, 1.60-fold, and 1.95-fold higher, respectively) and in MCF-7 cells (2.63-fold, 1.63-fold, and 1.85-fold higher, respectively). The subsequent cytotoxicity and in vivo assays further supported the dual-targeting liposome is a promising drug delivery carrier for the treatment of breast cancer.

Design, preparation and evaluation of different branched biotin modified liposomes for targeting breast cancer.

A series of liposome ligands (Bio-Chol, Bio-Bio-Chol, tri-Bio-Chol and tetra-Bio-Chol) modified by different branched biotins that can recognize the SMVT receptors over-expressed in breast cancer cells were synthesized. And four liposomes (Bio-Lip, Bio-Bio-Lip, tri-Bio-Lip and tetra-Bio-Lip) modified by above mentioned ligands as well as the unmodified liposome (Lip) were prepared to study the targeting ability for breast cancer. The cytotoxicity study and apoptosis assay of paclitaxel-loaded liposomes showed that tri-Bio-Lip had the strongest anti-proliferative effect on breast cancer cells. The cellular uptake studies on mice breast cancer cells (4T1) and human breast cancer cells (MCF-7) indicated tri-Bio-Lip possessed the strongest internalization ability, which was 5.21 times of Lip, 2.60 times of Bio-Lip, 1.67 times of Bio-Bio-Lip and 1.17 times of tetra-Bio-Lip, respectively. Moreover, the 4T1 tumor-bearing BALB/c mice were used to evaluate the in vivo targeting ability. The data showed the enrichment of liposomes at tumor sites were tri-Bio-Lip > tetra-Bio-Lip > Bio-Bio-Lip > Bio-Lip > Lip, which were consistent with the results of in vitro targeting studies. In conclusion, increasing the density of targeting molecules on the surface of liposomes can effectively enhance the breast cancer targeting ability, and the branching structure and spatial distance of biotin residues may also have an important influence on the affinity to SMVT receptors. Therefore, tri-Bio-Lip could be a promising drug delivery system for targeting breast cancer.

Dual-targeting liposomes with active recognition of GLUT5 and αvß3 for triple-negative breast cancer.

At present, chemo- and radiotherapies remain to be the mainstream methods for treating triple-negative breast cancer (TNBC), which is known for poor prognosis and high rate of mortality. Two types of novel dual-targeting TNBC liposomes (Fru-RGD-Lip and Fru+RGD-Lip) that actively recognize both fructose transporter GLUT5 and integrin αvß3 were designed and prepared in this work. Firstly, a Y-shaped Fru-RGD-chol ligand, where a fructose and peptide Arg-Gly-Asp (RGD) were covalently attached to cholesterol, was designed and synthesized. Then, the Fru-RGD-Lip was constructed by inserting Fru-RGD-chol into liposomes, while Fru+RGD-Lip was obtained by inserting both Fru-chol and RGD-chol (with the molar ratio of 1:1) into liposomes. The particle size, zeta potential, encapsulation efficiency and serum stability of the paclitaxel-loaded liposomes were characterized. The results indicated that the paclitaxel-loaded Fru-RGD-Lip had the strongest growth inhibition against GLUT5 and αvß3 overexpressed MDA-MB-231 and 4T1 cells. The cellular uptake of Fru-RGD-Lip on MDA-MB-231 cells and 4T1 cells was 3.19- and 3.23-fold more than that of the uncoated liposomes (Lip). The uptake of Fru+RGD-Lip was slightly lower, giving a 2.81- and 2.90-fold increase than that of Lip in two cell lines, respectively. The mechanism study demonstrated that the cellular uptake of both dual-targeting liposomes was likely to be recognized and mediated by GLUT5 and αvß3 firstly, then endocytosed through comprehensive pathways in an energy-dependent manner. Moreover, Fru-RGD-Lip displayed the maximum accumulation, which was 2.62-fold higher than that of Lip for instance, at the tumor sites compared to other liposomes using in vivo imaging. Collectively, the liposomes co-modified by fructose and RGD have enormous potential in the development of targeted TNBC treatment, especially the covalently modified Fru-RGD-Lip, making it a promising multifunctional liposome.