Gouty arthritis is a very familiar inflammatory arthritis. Controlling inflammation is the key to preventing gouty arthritis. However, colchicine, the most highly represented drug used in clinical practice, has strict contraindications owing to some severe side effects. Curcumin (Cur), a natural anti-inflammatory drug, has demonstrated good safety and efficacy. However, the rapid degradation, poor aqueous solubility, and low bioavailability of Cur limit its therapeutic effect. To strengthen the effectiveness and bioavailability of Cur. Cur loaded tetrahedral framework nucleic acids (Cur-TFNAs) were synthesized to deliver Cur. Compared with free Cur, Cur-TFNAs exhibit a preferable drug stability, good biocompatibility (CCK-8 assay), ease of uptake (immunofluorescence), and higher tissue utilization (in vivo biodistribution). Most importantly, Cur-TFNAs present better antiinflammatory effect than free Cur both in vivo and in vitro experiments through the determination of inflammation-related cytokines expression. Therefore, we believe that Cur-TFNAs have great prospects for the prevention of gout and similar inflammatory diseases.Peer review under responsibility of KeAi Communications Co., Ltd.
Rapid and efficient tools for early cancer detection have diagnostic and therapeutic value. Given that the DNA hairpin-based hybridization chain reaction (HCR) is effective in detecting various biological targets, a tetrahedral framework DNA-enhanced (TDN-enhanced) HCR detection system (T-probe system) is introduced for cancer-related targets and its versatility is demonstrated by detecting intracellular target miRNA 21 and cellular membrane target nucleolin. Benefiting from the spatial confinement of the TDN, the T-probe system demonstrates a high detection rate. It increases the reaction efficiency of nude hairpins in vitro while accurately and rapidly recognizing both membrane and intracellular cancer-related targets in living cells. Furthermore, it exhibits superior fluorescence in vivo within 15 s of peripheral-tumor injection and 10 min of tail-vein injection. The T-probe system efficiently and accurately images tumor-related biomarkers in vitro and in vivo, thereby demonstrating great potential for clinical diagnosis and therapeutic applications.
While the skin is considered the first line of defense in the human body, there are some vulnerabilities that render it susceptible to certain threats, which is an issue that is recognized by both patients and doctors. Cutaneous wound healing is a series of complex processes that involve many types of cells, such as fibroblasts and keratinocytes. This study showed that tetrahedral framework nucleic acids (tFNAs), a type of self-assembled nucleic-acid material, have the ability to promote keratinocyte(HaCaT cell line) and fibroblast(HSF cell line) proliferation and migration in vitro. In addition, tFNAs increased the secretion of vascular endothelial growth factor (VEGF) and basic fibroblast growth factor (bFGF) in HSF cells and reduced the production of tumor necrosis factor-alpha (TNF-α) and interleukin-1 beta (IL-1β) in HaCaT cells by activating the AKT-signaling pathway. During in vivo experiments, tFNA treatments accelerated the healing process in skin wounds and decreased the development of scars, compared with the control treatment that did not use tFNAs. This is the first study to demonstrate that nanophase materials with the biological features of nucleic acids accelerate the healing of cutaneous wounds and reduce scarring, which indicates the potential application of tFNAs in skin tissue regeneration.
DNA nanotechnology has provided new strategies and platforms for cargo delivery. However, DNA‐based nanostructures utilized for cargo delivery have mainly focused on static structures and passive targeting. Here, inspired by honeybee's natural reaction to hazards, a melittin loaded tetrahedron framework nucleic acid (tFNA) nanostructure, for active targeting therapy as a “nanobee” is developed. Upon exposure to target proteins on the cell membrane, the tFNA exoskeleton goes through conformation change, leading to the selective release of melittin from the exoskeleton and the consequent selective lethal effect. As a result, the active targeting of the nanobee to tumor cells is achieved. At the same concentrations of melittin, the nanobee exhibits significantly higher and more selective cytotoxicity against target cells than free melittin molecules, whereas the inactive nanobee shows neglectable lethal effect. Notably, the complete encapsulation of melittin in the tFNA exoskeleton is confirmed by the combination of experimental screening and molecular dynamic analysis, which is proposed to be the origin of the minimized off‐target effects of nanobee. This nanobee concept offers a strategy that may be extended to various dynamic stimuli‐responsive cargo delivery systems, to enhance cargo stability and decrease severe off‐target effects.
Obesity-induced insulin resistance is the hallmark of metabolic syndrome, and chronic, low-grade tissue inflammation links obesity to insulin resistance through the activation of tissue-infiltrating immune cells. Current therapeutic approaches lack efficacy and immunomodulatory capacity. Thus, a new therapeutic approach is needed to prevent chronic inflammation and alleviate insulin resistance. Here, we synthesized a tetrahedral framework nucleic acid (tFNA) nanoparticle that carried resveratrol (RSV) to inhibit tissue inflammation and improve insulin sensitivity in obese mice. The prepared nanoparticles, namely tFNAs-RSV, possessed the characteristics of simple synthesis, stable properties, good water solubility, and superior biocompatibility. The tFNA-based delivery ameliorated the lability of RSV and enhanced its therapeutic efficacy. In high-fat diet (HFD)-fed mice, the administration of tFNAs-RSV ameliorated insulin resistance by alleviating inflammation status. tFNAs-RSV could reverse M1 phenotype macrophages in tissues to M2 phenotype macrophages. As for adaptive immunity, the prepared nanoparticles could repress the activation of Th1 and Th17 and promote Th2 and Treg, leading to the alleviation of insulin resistance. Furthermore, this study is the first to demonstrate that tFNAs, a nucleic acid material, possess immunomodulatory capacity. Collectively, our findings demonstrate that tFNAs-RSV alleviate insulin resistance and ameliorate inflammation in HFD mice, suggesting that nucleic acid materials or nucleic acid-based delivery systems may be a potential agent for the treatment of insulin resistance and obesity-related metabolic diseases.
Retinal ischemia-reperfusion (I/R) injuries are involved in the universal pathological processes of many ophthalmic diseases, including glaucoma, diabetic retinopathy, and retinal arterial occlusion.
siRNA is found to effectively knock down the target gene in cells, which is considered a promising strategy for gene therapy. However, the application of siRNA is limited due to its low efficiency of the cellular uptake. Tetrahedral framework nucleic acids (tFNAs) are synthesized by four single-stranded DNAs and show multiple biological functions in recent studies, especially suitable for drug delivery. More than 60% of malignant melanomas are associated with Braf gene mutation, an attractive therapeutic target for RNA interference. In this study, we modified anti-Braf siRNA (siBraf) with tFNAs to downregulate the target gene. Meanwhile, we directly incorporated AS1411 (a DNA aptamer) to our nanostructure, which assists tFNAs to improve the cellular uptake efficacy of siBraf significantly. The results indicated that tFNAs-AS1411-siBraf exhibited more potent activity to cleave Braf mRNA than free siBraf. This study may provide a new idea for the combination therapy of siRNA and aptamers via DNA nanomaterials to achieve gene silencing.
Acute myocardial infarction, which can be extremely difficult to treat, is the worst deadly disease around the world. Reperfusion is expedient to reverse myocardial ischemia. However, during reperfusion, reactive oxygen species (ROS) produced by myocardial ischemia-reperfusion injury (MIRI) and further cell apoptosis are the most serious challenges to cardiomyocytes. Therefore, searching for reagents that can simultaneously reduce oxidative damage and MIRI-induced apoptosis is the pivotal strategy to rescue injured cardiomyocytes. Nevertheless, current cardioprotective drugs have some shortcomings, such as cardiotoxicity, inadequate intravenous administration, or immature technology. Previous studies have shown that tetrahedral DNA nanostructures (TDNs) have biological safety with promising anti-inflammatory and antioxidative potential. However, the progress that TDNs have made in the biological behavior of cardiomyocytes has not been explored. In this experiment, a cellular model of MIRI was first established. Then, confirmed by a series of experiments, our study indicates that TDNs can significantly decrease oxidative damage and apoptosis by limiting the overexpression of ROS, along with effecting the expression of apoptosis-related proteins. In addition, Western blot analysis demonstrated that TDNs could activate the Akt/Nrf2 signaling pathway to improve the myocardial injury induced by MIRI. Above all, the antioxidant and antiapoptotic capacities of TDNs make them a potential therapeutic drug for MIRI. This study provides new ideas and directions for more homogeneous diseases induced by oxidative damage.
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