Xiaoxi Xu

Encapsulated human hepatocellular carcinoma cells by alginate gel beads as an in vitro metastasis model.

Hepatocellular carcinoma (HCC) is the most common primary liver cancer and often forms metastases, which are the most important prognostic factors. For further elucidation of the mechanism underlying the progression and metastasis of HCC, a culture system mimicking the in vivo tumor microenvironment is needed. In this study, we investigated the metastatic ability of HCC cells cultured within alginate gel (ALG) beads. In the culture system, HCC cells formed spheroids by proliferation and maintained in nuclear abnormalities. The gene and protein expression of metastasis-related molecules was increased in ALG beads, compared with the traditional adhesion culture. Furthermore, several gene expression levels in ALG bead culture system were even closer to liver cancer tissues. More importantly, in vitro invasion assay showed that the invasion cells derived from ALG beads was 7.8-fold higher than adhesion cells. Our results indicated that the in vitro three-dimensional (3D) model based on ALG beads increased metastatic ability compared with adhesion culture, even partly mimicked the in vivo tumor tissues. Moreover, due to the controllable preparation conditions, steady characteristics and production at large-scale, the 3D ALG bead model would become an important tool used in the high-throughput screening of anti-metastasis drugs and the metastatic mechanism research.

Role of three‐dimensional matrix stiffness in regulating the chemoresistance of hepatocellular carcinoma cells

Hepatocellular carcinoma (HCC) was the most common primary liver cancer, and its resistance to anti‐tumor drugs often caused the death of patients suffering with HCC. Matrix stiffness was reported to be closely related to tumor chemoresistance; however, the relationship between HCC drug resistance and three‐dimensional (3D) matrix stiffness is still unclear at present. In this study, alginate gel (ALG) beads with controllable matrix stiffness were used to mimic tumor tissue rigidity, and the role of 3D matrix stiffness in regulating the chemoresistance of HCC cells was investigated by using these ALG beads. It was found that HCC cells in ALG beads with 105 kPa stiffness had highest resistance to paclitaxel, 5‐FU, and cisplatin. Although the mechanism was still uncovered, ABC transporters and endoplasmic reticulum stress‐related molecules were highly expressed in ALG bead‐encapsulated HCC cells compared with two‐dimensional‐cultured cells, which suggested a very complex mechanism underlying HCC drug resistance in 3D culture conditions. In addition, to mimic the specific stiffness of HCC tumor tissue, or other tumor tissues in vivo, response surface methodology (RSM) was used to build up a prediction mathematical model so that ALG beads with desired matrix stiffness could be prepared by simply changing three factors: molecular weight, G content, and alginate concentration.

Enrichment of cancer stem cell-like cells by culture in alginate gel beads

Cancer stem cells (CSCs) are most likely the reason of cancer reoccurrence and metastasis. For further elucidation of the mechanism underlying the characteristics of CSCs, it is necessary to develop efficient culture systems to culture and expand CSCs. In this study, a three-dimensional (3D) culture system based on alginate gel (ALG) beads was reported to enrich CSCs. Two cell lines derived from different histologic origins were encapsulated in ALG beads respectively and the expansion of CSCs was investigated. Compared with two-dimensional (2D) culture, the proportion of cells with CSC-like phenotypes was significantly increased in ALG beads. Expression levels of CSC-related genes were greater in ALG beads than in 2D culture. The increase of CSC proportion after being cultured within ALG beads was further confirmed by enhanced tumorigenicity in vivo. Moreover, increased metastasis ability and higher anti-cancer drug resistance were also observed in 3D-cultured cells. Furthermore, we found that it was hypoxia, through the upregulation of hypoxia-inducible factors (HIFs) that occurred in ALG beads to induce the increasing of CSC proportion. Therefore, ALG bead was an efficient culture system for CSC enrichment, which might provide a useful platform for CSC research and promote the development of new anti-cancer therapies targeting CSCs.

Injectable in situ forming chitosan-based hydrogels for curcumin delivery

AbstractIn this paper, a series of injectable in situ forming chitosan-based hydrogels were prepared by chemical crosslinking of chitosan and genipin with the cooperation of ionic bonds between chitosan and sodium salts at room temperature. Four hydrogels (A, B, C, and D) were obtained by mixing chitosan, genipin and a sodium salt of trisodium phosphate (Na3PO4·12H2O), sodium sulfate (Na2SO4), sodium sulfite (Na2SO3), or sodium bicarbonate (NaHCO3) and examined for their characteristics, morphology, and rheological properties. Their cell viability assays exhibited low toxicity and the localized in situ gel formation was detected after subcutaneous injections in rat. Curcumin which possesses many pharmaceutical potentials but has low bioavailability, was chosen as a drug model. In vitro curcumin release profiles exhibit sustained release properties with initial burst release for all hydrogels with about 3 to 6 times higher cumulative release than other gel controls. The results of this study demonstrate that our hydrogels have a potential as local curcumin carriers.

Potential effect of matrix stiffness on the enrichment of tumor initiating cells under three-dimensional culture conditions.

Cancer stem cell (CSC) or tumor initiating cell (TIC) plays an important role in tumor progression and metastasis. Biophysical forces in tumor microenvironment have an important effect on tumor formation and development. In this study, the potential effect of matrix stiffness on the biological characteristics of human head and neck squamous cell carcinoma (HNSCC) TICs, especially the enrichment of HNSCC TICs, was investigated under three-dimensional (3D) culture conditions by means of alginate gel (ALG) beads with different matrix stiffnesses. ALG beads with soft (21 kPa), moderate (70 kPa) and hard (105 kPa) stiffness were generated by changing alginate concentration. It was found that significant HNSCC TIC enrichment was achieved in the ALG beads with moderate matrix stiffness (70 kPa). The gene expression of stemness markers Oct3/4 and Nanog, TIC markers CD44 and ABCG2 was enhanced in cells under this moderate (70 kPa) stiffness. HNSCC TIC proportion was also highly enriched under moderate matrix stiffness, accompanying with higher tumorigenicity, metastatic ability and drug resistance. And it was also found that the possible molecular mechanism underlying the regulated TIC properties by matrix stiffness under 3D culture conditions was significantly different from 2D culture condition. Therefore, the results achieved in this study indicated that 3D biophysical microenvironment had an important effect on TIC characteristics and alginate-based biomimetic scaffolds could be utilized as a proper platform to investigate the interaction between tumor cells and 3D microenvironment.

The effect of electrostatic microencapsulation process on biological properties of tumour cells

Microencapsulation is one of the promising strategies to develop a three-dimensional in vivo tumour-mimic model in cancer research. Although previous studies have shown that tumour cells grow well during the microencapsulated culture, it is still not clear whether the electrostatic encapsulation process has an important effect on cellular characteristics. In this study, we investigated cellular response against non-physiological stress factors existing in the electrostatic microencapsulation process, such as the high-voltage electrostatic field, suspension and nutrition-free status. Our results showed that these non-physiological stress factors did not significantly induce cellular apoptosis, and did not affect cellular adhesion and viability. Furthermore, no change was found about invasion and drug resistance of the tumour cells. The normal endoplasmic reticulum function might play a role in maintaining biological properties during the electrostatic microencapsulation process.

Mesenchymal stem cells enhance the metastasis of 3D-cultured hepatocellular carcinoma cells

BackgroundAccumulating evidences have demonstrated that mesenchymal stem cells (MSC) could be recruited to the tumor microenvironment. Umbilical cord mesenchymal stem cells (UCMSC) were attractive vehicles for delivering therapeutic agents against cancer. Nevertheless, the safety of UCMSC in the treatment of tumors including hepatocellular carcinoma (HCC) was still undetermined.MethodsIn this study, an in vitro co-culture system was established to evaluate the effect of UCMSC on the cell growth, cancer stem cell (CSC) characteristics, drug resistance, metastasis of 3D-cultured HCC cells, and the underlying mechanism was also investigated.ResultsIt was found that after co-cultured with UCMSC, the metastatic ability of 3D-cultured HCC cells was significantly enhanced as indicated by up-regulation of matrix metalloproteinase (MMP), epithelial-mesenchymal transition (EMT)-related genes, and migration ability. However, cell growth, drug resistance and CSC-related gene expression of HCC cells were not affected by UCMSC. Moreover, EMT was reversed, MMP-2 expression was down-regulated, and migration ability of HCC cell was significantly inhibited when TGF-β receptor inhibitor SB431542 was added into the co-culture system.ConclusionsTherefore, these data indicated that UCMSC could significantly enhance the tumor cell metastasis, which was due to the EMT of HCC cells induced by TGF-β.