Acute lymphoblastic leukemia (ALL) initiates and progresses in the bone marrow, and as such, the marrow microenvironment is a critical regulatory component in development of this cancer. However, ALL studies were conducted mainly on flat plastic substrates, which do not recapitulate the characteristics of marrow microenvironments. To study ALL in a model of in vivo relevance, we have engineered a 3-D microfluidic cell culture platform. Biologically relevant populations of primary human bone marrow stromal cells, osteoblasts and human leukemic cells representative of an aggressive phenotype were encapsulated in 3-D collagen matrix as the minimal constituents and cultured in a microfluidic platform. The matrix stiffness and fluidic shear stress were controlled in a physiological range. The 3-D microfluidic as well as 3-D static models demonstrated coordinated cell-cell interactions between these cell types compared to the compaction of the 2-D static model. Tumor cell viability in response to an antimetabolite chemotherapeutic agent, cytarabine in tumor cells alone and tri-culture models for 2-D static, 3-D static and 3-D microfluidic models were compared. The present study showed decreased chemotherapeutic drug sensitivity of leukemic cells in 3-D tri-culture models from the 2-D models. The results indicate that the bone marrow microenvironment plays a protective role in tumor cell survival during drug treatment. The engineered 3-D microfluidic tri-culture model enables systematic investigation of effects of cell-cell and cell-matrix interactions on cancer progression and therapeutic intervention in a controllable manner, thus improving our limited comprehension of the role of microenvironmental signals in cancer biology.
As acute myocardial infarction (AMI) has now become a severe death threat to humans and may abruptly occur at home or outdoors where sophisticated equipment is not available, it is of great importance to develop facile methodologies for the point-of-care (POC) diagnosis of AMI. Toward this goal, here we build a sensing platform for chemiluminescence (CL) microRNA (miRNA) imaging with a smartphone as the portable detector, and for the first time we achieve visualization of AMI-related miRNAs in real patients' serum. We first construct a spherical nucleic acid enzyme (termed SNAzyme) derived from a dense layer of G-quadruplex (G4) DNAzyme formed on the gold nanoparticle core, which displays ∼100-fold and higher catalytic activity and improved resistance to nuclease degradation in a real blood sample as compared to those of the G4 DNAzyme itself. These unique features endow the SNAzyme-boosted CL platform with superior imaging performance for analyzing an AMI-related miRNA, miRNA-133a. This miRNA is employed to trigger the target-catalyzed hairpin assembly to produce a sticky dsDNA linker that captures the SNAzyme nanolabel onto the substrate. In this way, miRNA-133a is successfully detected, with a limit of detection of 0.3 pM (S/N = 3) and a high selectivity over other miRNA analogs in patients' blood. Given its unique features in physiological environments, our SNAzyme-boosted imaging platform holds great promise for use in the POC diagnosis of AMI.
Background Glioblastoma (GBM) is a fatal brain tumor, lacking effective treatment. Epidermal growth factor receptor (EGFR) is recognized as an attractive target for GBM treatment. However, GBMs have very poor responses to the first- and second-generation EGFR inhibitors. The third-generation EGFR-targeted drug, AZD9291, is a novel and irreversible inhibitor. It is noteworthy that AZD9291 shows excellent blood–brain barrier penetration and has potential for the treatment of brain tumors. Methods In this study, we evaluated the anti-tumor activity and effectiveness of AZD9291 in a preclinical GBM model. Results AZD9291 showed dose-responsive growth inhibitory activity against six GBM cell lines. Importantly, AZD9291 inhibited GBM cell proliferation > 10 times more efficiently than the first-generation EGFR inhibitors. AZD9291 induced GBM cell cycle arrest and significantly inhibited colony formation, migration, and invasion of GBM cells. In an orthotopic GBM model, AZD9291 treatment significantly inhibited tumor survival and prolonged animal survival. The underlying anti-GBM mechanism of AZD9291 was shown to be different from that of the first-generation EGFR inhibitors. In contrast to erlotinib, AZD9291 continuously and efficiently inhibited the EGFR/ERK signaling in GBM cells. Conclusion AZD9291 demonstrated an efficient preclinical activity in GBM in vitro and in vivo models . AZD9291 has been approved for the treatment of lung cancer with good safety and tolerability. Our results support the possibility of conducting clinical trials of anti-GBM therapy using AZD9291. Electronic supplementary material The online version of this article (10.1186/s13046-019-1235-7) contains supplementary material, which is available to authorized users.
Inflammatory bowel disease (IBD) comprises a group of chronic inflammatory disorders of the gastrointestinal tract. Accumulating evidence shows that the development of IBD is always accompanied by the dysbiosis of the gut microbiota (GM), causing a decrease in prebiotic levels and an increase in harmful metabolite levels. This leads to persistent immune response and inflammation in the intestine, greatly impairing the physiological function of the gastrointestinal tract. Short-chain fatty acids (SCFAs) are produced by probiotic gut bacteria from a fiber-rich diet that cannot be digested directly. SCFAs with significant anti-inflammatory functions regulate immune function and prevent an excessive immune response, thereby delaying the clinical progression of IBD. In this review, we summarize the generation of SCFAs and their potential therapeutic effects on IBD. Furthermore, we suggest that SCFAs may modulate innate immune recognition and cytokine production to intervene in the progression of IBD. Additional randomized controlled trials and prospective cohort studies should also investigate the clinical impact of SCFA.
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