Guanidinium Hydrophobic Magnetic Ionic Liquid-Based Dispersive Droplet Extraction for the Selective Extraction of DNA

Spin Glass Transition of Magnetic Ionic Liquids Induced by Self-Assembly

Spin glass (SG), in which the spins are glassy, has attracted broad attention for theoretical study and prospective application. SG states are generally related to disordered or frustrated spin systems, which are usually observed in inorganic magnets. Herein, supramolecular magnetic ionic liquid (TMTBDI[FeCl4]) self-assemblies are prepared by solution self-assembly via hydrophobic and π-π stacking interactions. The supramolecular self-assemblies are in short-range lattice ordering and long-range disordering structures, as the lattice self-assemblies with the tens of nanometer scale are distributed randomly to form a long-range disorder. The shortest Fe(III)-Fe(III) distance is calculated to be ca. 2.4 Å from transmission electron microscopy (TEM) results. The magnetic properties of the supramolecular self-assemblies are studied via direct current (DC) and alternating current (AC) magnetic susceptibility characterizations. It is noted that TMTBDI[FeCl4] is paramagnetic before self-assembly. However, the supramolecular self-assemblies exhibit a strong ferromagnetic interaction due to the short Fe(III)-Fe(III) distance. The AC results show that the supramolecular self-assemblies are in the SG state at low temperatures as the imaginary part of the susceptibility moves to high temperatures with frequency. The self-assembly-induced spin glass transition of TMTBDI[FeCl4] is due to the long-range disordering and short-range ordering structures of the self-assemblies, which induces a frustrated spin system.

Detection of extracellular antibiotic resistance genes in river water: Application of ultrafiltration-magnetic beads method

Antibiotic resistance genes (ARGs) are widespread contaminants that pose significant threats to public health. Rivers play a crucial role in the dissemination of ARGs within the aquatic environment. However, there are limitations in the current research on the differentiation of intracellular ARGs (iARGs) and extracellular ARGs (eARGs) in river water. In this study, we developed a method combining ultrafiltration and adsorption of silica-hydroxy magnetic beads for efficient extraction of extracellular DNA (eDNA) from river water. The conditions of adsorption, washing, desorption, and pretreatment were optimized to enhance eDNA recovery. By using only 90 mL of water sample, our method could collect sufficient eDNA for subsequent detection of eARGs through qPCR analysis. The eDNA recovery rate ranged from 51.4% to 69.8%. The occurrence of five prevalent ARGs (tetC, sulI, blaTEM, ermB, qnrS) as well as integrase gene intl1 were investigated in both iDNA and eDNA extracted from river water samples collected from two tributaries of the Pearl River. Our results revealed that the absolute abundance levels of eARGs ranged from 10-1 to 105 copies/mL, which were significantly higher than those observed for iARGs ranging from 10-1 to 104 copies/mL. Moreover, there was a significant difference in contamination profiles for ARGs between two tributaries. The ultrafiltration-magnetic beads method overcomes challenges associated with low efficiency extraction when working with water samples containing low nucleic acid concentrations. This approach provides an improved technique for extracting eARGs from river water while also generating valuable data supporting assessments related to eARG contamination in such environments.

Selective extraction of genomic DNA from leopard cat (Prionailurus bengalensis), hairy-crowned deer (Elaphodus cephalophus) and muntjac (Muntiacus reevesi) using hydrophobic magnetic deep eutectic solvents

Wild animals, as a vital component of our natural world, serve a crucial role in preserving ecological equilibrium and biodiversity. By delving into the genetic constitution of wild animal populations, the evolutionary history, genetic diversity, and adaptation mechanisms could be explored, thereby informing conservation strategies and safeguarding the future of these species. In order to study the genetic information of wild animals, it is necessary to extract high purity and high concentration of wild animal genomic DNA. In this work, a hydrophobic magnetic deep eutectic solvent (HMDES) based vortexed extraction was developed for the extraction of genomic DNA from leopard cat (Prionailurus bengalensis), hairy-crowned deer (Elaphodus cephalophus) and muntjac (Muntiacus reevesi) muscle tissue, respectively. Extraction conditions like the pH value, extraction time, temperature and the amount of HMDES used were optimized by single-factor experiments. Under the optimized condition, genomic DNA could be selectively extracted from the three animal tissues. The limits of detection (LOD) and limits of quantification (LOQ) of the proposed method were 2.86 ng/μL and 8.66 ng/μL, respectively. Meanwhile, the relative standard deviation (RSD) of the method precision and repeatability were 1.64 % and 5.57 % at 20 ng/μL, showing the method has good precision and repeatability. After extraction, the DNA extracted into the HMDES droplets can be quickly recovered and the HMDES can be recycled and reused. The method proposed is a fast, environmental-friendly and high efficient extraction strategy for purification and enrichment of genomic DNA from leopard cat, hairy-crowned deer and muntjac tissues.

Research Progress of Nucleic Acid Detection Technology for Genetically Modified Maize

Genetically modified (GM) maize is one of the earliest GM crops to have achieved large-scale commercial cultivation globally, and it is of great significance to excel in the development and implementation of safety policy regarding GM, and in its technical oversight. This article describes the general situation regarding genetically modified maize, including its varieties, applications, relevant laws and regulations, and so on. From a technical point of view, we summarize and critically analyze the existing methods for detecting nucleic acid levels in genetically modified maize. The nucleic acid extraction technology used for maize is explained, and the introduction of traditional detection techniques, which cover variable-temperature and isothermal amplification detection technology and gene chip technology, applications in maize are described. Moreover, new technologies are proposed, with special attention paid to nucleic acid detection methods using sensors. Finally, we review the current limitations and challenges of GM maize nucleic acid testing and share our vision for the future direction of this field.

Isolation of DNA from plant tissues using a miniaturized matrix solid-phase dispersion approach featuring ionic liquid and magnetic ionic liquid solvents

The isolation of high-quality plant genomic DNA is a major prerequisite in many plant biomolecular analyses involving nucleic acid amplification. Conventional plant cell lysis and DNA extraction methods involve lengthy sample preparation procedures that often require large amounts of sample and chemicals, high temperatures and multiple liquid transfer steps which can introduce challenges for high throughput applications. In this study, a simple, rapid, miniaturized ionic liquid (IL)-based extraction method was developed for the isolation of genomic DNA from milligram fragments of Arabidopsis thaliana plant tissue. This method is based on a modification of vortex-assisted matrix solid-phase dispersion (VA-MSPD) in which the trihexyl(tetradecyl)phosphonium bis(trifluoromethylsulfonyl)imide ([P_6,6,6,14⁺][NTf₂^-]) IL or trihexyl(tetradecyl)phosphonium tris(hexafluoroacetylaceto)nickelate(II) ([P_6,6,6,14⁺][Ni(hfacac)₃^-]) magnetic IL (MIL) was directly applied to treated plant tissue (∼1.5 mg) and dispersed in an agate mortar to facilitate plant cell lysis and DNA extraction, followed by recovery of the mixture with a qPCR compatible co-solvent. This study represents the first approach to use ILs and MILs in a MSPD procedure to facilitate plant cell lysis and DNA extraction. The DNA-enriched IL- and MIL-cosolvent mixtures were directly integrated into the qPCR buffer without inhibiting the reaction while also circumventing the need for additional purification steps prior to DNA amplification. Under optimum conditions, the IL and MIL yielded 2.87 ± 0.28 and 1.97 ± 0.59 ng of DNA/mg of plant tissue, respectively. Furthermore, the mild extraction conditions used in the method enabled plant DNA in IL- and MIL-cosolvent mixtures to be preserved from degradation at room temperature.

Applications of magnetic and electromagnetic forces in micro-analytical systems

Novel applications of magnetic fields in analytical chemistry have become a remarkable trend in the last two decades. Various magnetic forces have been employed for the migration, orientation, manipulation, and trapping of microparticles, and new analytical platforms for separating and detecting molecules have been proposed. Magnetic materials such as functional magnetic nanoparticles, magnetic nanocomposites, and specially designed magnetic solids and liquids have also been developed for analytical purposes. Numerous attractive applications of magnetic and electromagnetic forces on magnetic and non-magnetic materials have been studied, but fundamental studies to understand the working principles of magnetic forces have been challenging. These studies will form a new field of magneto-analytical science, which should be developed as an interdisciplinary field. In this review, essential pioneering works and recent attractive developments are presented.

Multi-magnetic center ionic liquids for dispersive liquid-liquid microextraction coupled with in-situ decomposition based back-extraction for the enrichment of parabens in beverage samples

In this paper, several new multi-magnetic center magnetic ionic liquids (MMILs) were prepared with paramagnetic component simultaneously contained in both the cation and anion and used as extractants to establish a dispersive liquid-liquid microextraction (DLLME) approach followed by in-situ MMIL decomposition based back-extraction for the enrichment and determination of four parabens in beverages. The appropriate MMIL was selected by investigating the extraction performances of the obtained MMILs combined with high performance liquid chromatography-ultraviolet detection (HPLC-UV), and some other experimental factors were explored. Under the optimized DLLME conditions, the four parabens exhibited coefficients of determination (R²) above 0.9987 in the linear range of 0.1-500 ng·mL^-1 for ethylparaben, propylparaben and butylparaben and 0.2-500 ng·mL^-1 for methylparaben. The limits of detection (LODs) and limits of quantification (LOQs) were respectively within 0.03-0.06 ng·mL^-1 and 0.1-0.2 ng·mL^-1, and the relative standard deviations (RSDs) for intra-day and inter-day precision were below 10.8%. Moreover, the application of the developed MMIL-based DLLME method in beverage samples exhibited recoveries within 81.3%-112.1% with RSDs of 0.3%-13.1% at three different spiked levels.

Assessing the Suitability of a Dicationic Ionic Liquid as a Stabilizing Material for the Storage of DNA in Aqueous Medium

The present study has been undertaken with an objective to find out a suitable medium for the long-term stability and storage of the ct-DNA structure in aqueous solution. For this purpose, the potential of a pyrrolidinium-based dicationic ionic liquid (DIL) in stabilizing ct-DNA structure has been investigated by following the DNA-DIL interaction. Additionally, in order to understand the fundamental aspects regarding the DNA-DIL interaction in a comprehensive manner, studies are also done by employing structurally similar monocationic ionic liquids (MILs). The investigations have been carried out both at ensemble-average and single molecular level by using various spectroscopic techniques. The molecular docking study has also been performed to throw more light into the experimental observations. The combined steady-state and time-resolved fluorescence, fluorescence correlation spectroscopy, and circular dichroism measurements have demonstrated that DILs can effectively be used as better storage media for ct-DNA as compared to MILs. Investigations have also shown that the extra electrostatic interaction between the cationic head group of DIL and the phosphate backbone of DNA is primarily responsible for providing better stabilization to ct-DNA, retaining its native structure in aqueous medium. The outcomes of the present study are also expected to provide valuable insights in designing new polycationic IL systems that can be used in nucleic acid-based applications.