Microfluidic Chip System Research Articles

Fully Automatic Multi-Class Multi-Residue Analysis of Veterinary Drugs Simultaneously in an Integrated Chip-MS Platform.

Microfluidic chip analysis has great potential advantages such as high integration, fast speed analysis, and automatic operation and is widely used not only in biological fields but also in many other analytical areas such as agriculture and food safety. Herein, a fully automatic multi-class multi-residue analysis of veterinary drugs simultaneously in an integrated chip-mass spectrometry (chip-MS) platform was developed. The developed microfluidic chip platform integrated three modules including the extraction and filtration module, "pass-through" clean-up module, and online evaporation module. The resulting chip has been coupled to a MS detector successfully, in which 23 kinds of residues in five classes were simultaneously qualitatively and quantitatively detected without chromatographic separation, obtaining the limits of detection of the spiked milk sample in the range of 0.23-4.13 ng/mL and the recovery rate in the range from 71.7 to 118.0% under optimized conditions. The microfluidic chip system developed in this study provided a new idea for the development of detection chips and exhibited considerable potential in the point-of-care testing in milk.

Microfluidic Biosensor for Rapid Nucleic Acid Quantitation Based on Hyperspectral Interferometric Amplicon-Complex Analysis.

Nucleic acid detection plays a vital role in both biomedical research and clinical medicine. The temperature circulation changes of the widely used polymerase chain reaction technique are time-consuming and technically challenging for system development. Recombinase polymerase amplification (RPA) is an isothermal method for rapid nucleic acid detection. However, current RPA amplicon detection methods are complicated and expensive and easily generate false positives, restricting the promotion of RPA techniques. In this work, a hyperspectral interferometric amplicon-complex quantitation method is presented, combined with asymmetric dipole complex strategy optical scattering analysis. GelRed dye was utilized to form amplicon-complex particles, and the Fourier domain spectrum computation contributed to complex scattering quantitation. With this method, a supporting microfluidic chip and automatic system were developed to achieve integrated, rapid, quantitative, and miniscule nucleic acid detection. The Plasmodium falciparumdhfr gene was utilized as an example for targeted nucleic acid quantitation and single nucleotide polymorphism detection. The total reaction time was decreased to merely 20 min, and the limit of detection was only 3.17 ng/μL. The minimum measurable concentration of target was 1.68 copies/μL, 31.67 times more sensitive than turbidity detection, and the single reaction chamber was only 9.33 μL. No scattering increase occurred for template-free control, and thus, false positives caused by primer dimers and nonspecific products could be avoided. The experimental results prove that the provided method and system can detect single-base mutations in the dhfr gene and is a reasonable technique for rapid, automatic, and low-cost nucleic acid detection.

Microfluidic 3D intestine tumor spheroid model for efficient in vitro investigation of nanoparticular formulations

For the treatment of intestinal tumors by oral administration of drugs, the mucus layer of the intestine represents a barrier, but also a target possibility for drug. The use of nanoparticular drug delivery systems is an important tool to improve the transport and accumulation of the drug on the target side. Therefore, specific in vitro test systems to simulate the conditions of an intestine tumor are necessary for the screening and efficiency testing of potential new nanoparticular drug delivery systems. Here, we introduce a microfluidic 3D intestine tumor spheroid model, which allows to test functionalized nanoparticles and their ability to adsorb onto and permeate over a mucus layer under dynamic conditions. More specifically, the model consists of a 3D tumor spheroid with a mucus layer and microvilli on the surface, which is placed into a microfluidic chip system. The system incorporates a fluid flow, which is an important factor in nanoparticle residence time and uptake. To test the microfluidic 3D intestine tumor spheroid model, two different nanoparticle systems surfaces-coated with Carbopol® or Pluronic® F127 were produced to test the adsorption and permeation over the mucus layer. The data showed obvious adsorptive and permeable properties of uncoated and surface-coated nanoparticles in the static and dynamic system. The 3D intestine tumor spheroid model has the potential to significantly advance the preclinical development of new drugs like nanoparticles.

Multiplex and on-site PCR detection of swine diseases based on the microfluidic chip system

BackgroundAt present, the process of inspection and quarantine starts with sampling at the customs port, continues with transporting the samples to the central laboratory for inspection experiments, and ends with the inspected results being fed back to the port. This process had the risks of degradation of biological samples and generation of pathogenic microorganisms and did not meet the rapid on-site detection demand because it took a rather long time. Therefore, it is urgently needed to develop a rapid and high-throughput detection assay of pathogenic microorganisms at the customs port. The aim of this study was to develop a microfluidic chip to rapidly detect swine pathogenic microorganisms with high-throughput and higher accuracy. Moreover, this chip will decrease the risk of spreading infection during transportation.ResultsA series of experiments were performed to establish a microfluidic chip. The resulting data showed that the positive nucleic acid of four swine viruses were detected by using a portable and rapid microfluidic PCR system, which could achieve a on-site real-time quantitative PCR detection. Furthermore, the detection results of eight clinical samples were obtained within an hour. The lowest concentration that amplified of this microfluidic PCR detection system was as low as 1 copies/μL. The results showed that the high specificity of this chip system in disease detection played an important role in customs inspection and quarantine during customs clearance.ConclusionThe microfluidic PCR detection system established in this study could meet the requirement for rapid detection of samples at the customs port. This chip could avoid the risky process of transporting the samples from the sampling site to the testing lab, and drastically reduce the inspection cycle. Moreover, it would enable parallel inspections on one chip, which greatly raised the efficiency of inspection.

Deskilled and Rapid Drug-Resistant Gene Detection by Centrifugal Force-Assisted Thermal Convection PCR Device.

Here we report the improved Cyclo olefin polymer (COP) microfluidic chip and polymerase chain reaction (PCR) amplification system for point-of-care testing (POCT) in rapid detection of Carbapenem-resistant Enterobacteriaceae (CRE). The PCR solution and thermal cycling is controlled by the relative gravitational acceleration (7G) only and is expected to pose minimal problem in operation by non-expert users. Detection is based on identifying the presence of carbapenemase encoding gene through the corresponding fluorescence signal after amplification. For preliminary tests, the device has been demonstrated to detect blaIMP-6 from patients stool samples. From the prepared samples, 96.4 fg/µL was detected with good certainty within 15 min (~106 thermocycles,) which is significantly faster than the conventional culture plate method. Moreover, the device is expected to detect other target genes in parallel as determination of the presence of blaNDM-1 and blaOXA-23 from control samples has also been demonstrated. With the rising threat of drug-resistant bacteria in global healthcare, this technology can greatly aid the health sector by enabling the appropriate use of antibiotics, accelerating the treatment of carriers, and suppressing the spread.

Cryopreservation of a cell-based biosensor chip modified with elastic polymer fibers enabling ready-to-use on-site applications

An efficient preservation of a cell-based biosensor chip to achieve a ready-to-use on-site system is still very challenging as the chip contains a living component such as adherent mammalian cells. Herein, we propose a strategy called on-sensor cryopreservation (OSC), which enables the adherent cells to be preserved by freezing (−80 °C) on a biosensor surface, such as the light-addressable potentiometric sensor (LAPS). Adherent cells on rigid surfaces are prone to cryo-injury; thus, the surface was modified to enhance the cell recovery for OSC. It relies on i) the integration of elastic electrospun fibers composed of polyethylene vinyl acetate (PEVA), which has a high thermal expansion coefficient and low glass-transition temperature, and ii) the treatment with O2 plasma. The modified sensor is integrated into a microfluidic chip system not only to decrease the thermal mass, which is critical for fast thawing, but also to provide a precisely controlled micro-environment. This novel cryo-chip system is effective for keeping cells viable during OSC. As a proof-of-concept for the applicability of a ready-to-use format, the extracellular acidification of cancer cells (CHO-K1) was evaluated by differential LAPS measurements after thawing. Results show, for the first time, that the OSC strategy using the cryo-chip allows label-free and quantitative measurements directly after thawing, which eliminates additional post-thaw culturing steps. The freezing of the chips containing cells at the manufacturing stage and sending them via a cold-chain transport could open up a new possibility for a ready-to-use on-site system.

Quantitative and specific detection of viable pathogens on a portable microfluidic chip system by combining improved propidium monoazide (PMAxx) and loop-mediated isothermal amplification (LAMP).

An accurate and specific detection of viable Candida albicans (C. albicans) in vaginal discharge is crucial for the diagnosis of vulvovaginal candidiasis (VVC) and assessment of antifungal effects. In this study, improved propidium monoazide (PMAxx) and loop-mediated isothermal amplification (LAMP) were used for the first time to distinguish between viable and dead C. albicans. A portable microfluidic chip system was developed to detect multiple viable pathogens in parallel. The consumption of samples and reagents in per reaction cell were only 0.94 μL, less than 1/25 of the conventional 25 μL Eppendorf tubular test method, both significantly reducing testing cost and greatly simplifying the detection of multiple viable pathogens. The concentration of PMAxx was optimized against C. albicans at 4.0 log CFU mL-1 to 5.0 log CFU mL-1, and 1 μM PMAxx was proven to be suitable for the detection of C. albicans in clinical samples. When testing mixtures containing different ratios of viable to dead C. albicans, PMAxx-LAMP could circumvent the signal arising from dead cells and, therefore, reflected the abundance of viable cells precisely. Furthermore, the suitability of this technique to evaluate the effects of antifungal agents, including clotrimazole, miconazole, and tioconazole, was assessed. Finally, the viability of Escherichia coli (E. coli) and C. albicans were detected on the portable microfluidic chip system. PMAxx-LAMP based portable microfluidic chip system was determined to be a feasible technique for assessing the viability of multiple pathogens in gynecology and might provide insights into new VVC treatment strategies.

Integration of segmented microflow chemistry and online HPLC/MS analysis on a microfluidic chip system enabling enantioselective analyses at the nanoliter scale.

In this work, we introduce an approach to merge droplet microfluidics with an HPLC/MS functionality on a single chip to analyze the contents of individual droplets. This is achieved by a mechanical rotor-stator interface that precisely positions a microstructured PEEK rotor on a microfluidic chip in a pressure-tight manner. The developed full-body fused silica chip, manufactured by selective laser-induced etching, contained a segmented microflow compartment followed by a packed HPLC channel, which were interconnected by the microfluidic PEEK rotor on the fused silica lid with hair-thin through-holes. This enabled the targeted and leakage-free transfer of 10 nL fractions of droplets as small as 25 nL from the segmented microflow channel into the HPLC compartment that operated at pressures of up to 60 bar. In a proof of concept study, this approach was successfully applied to monitor reactions at the nanoliter scale and to distinguish the formed enantiomers.

Comparison of microfluidic and swim-up sperm separation methods for IVF

Abstract Sperm separation for ICSI is an essential step in realization of the IVF procedures. The method of microfluidic separation of sperm cells using chips has been applied more and more frequently in recent years. This method is often presented as extremely gentle to spermatozoa and decreasing significantly concentration of sperm cells with fragmented DNA when compared to conventional methods. The aim of our study was to verify a microfluidic chip system from the perspective of its potential to select spermatozoa with non-fragmented DNA. We tested the efficiency of this separation method against the swim-up method. In this study we evaluated sperm DNA integrity before and after the separation methods in ten patients. Ejaculate of each patient was separated by both the swim up method and the microfluidic chip method at the same time. It was shown that both the methods are very similar in reduction of spermatozoa with fragmented DNA. Interestingly, the concentration of spermatozoa with fragmented DNA was lower after the microfluidic separation than after the swim-up method in all the patients. Nevertheless, the differences were not statistically significant with only 2.1% on average, which is negligible in terms of practical use. Running title: Microfluidic chip and DNA fragmentation

Improved efficiency of urine cell image segmentation using droplet microfluidics technology.

Recent advances in the recognition of biological samples using machine vision have made this technology increasingly important in research and detection. Image segmentation is an important step in this process. This study focuses on how to reduce the interference factors such as the overlap between different types (or within the same type) of urine cells according to microfluidics and improve the machine vision segmentation accuracy for cell images. In this study, we demonstrate that the platform can realize this hypothesis using urine cell image segmentation as an example application. We first discuss the reported urine cell droplet microfluidic chip system, which can realize the test conditions in which urine cells are encapsulated in the droplet and isolated from salt crystallization and/or bacteria and other urine-formed elements. Then, based on the analysis conditions set in the aforementioned experiment, the proportions of red blood cells, white blood cells, and squamous epithelial cells covered by various formed elements in the total urine cells in the same urine sample are measured. We simultaneously analyze the percentage of urine cells covered by salt crystallization and the incidence of overlapping between urine cells. Finally, the Otsu algorithm is used to segment the urine cell images encapsulated by the droplet and the urine cell images not encapsulated by the droplet, and the Dice, Jaccard, precision, and recall values are calculated. The results suggest that the method of encapsulating single cells based on droplets can improve the image segmentation effect without optimizing the algorithm.

Compressed Air-Driven Continuous-Flow Thermocycled Digital PCR for HBV Diagnosis in Clinical-Level Serum Sample Based on Single Hot Plate.

We report a novel compressed air-driven continuous-flow digital PCR (dPCR) system based on a 3D microfluidic chip and self-developed software system to realize real-time monitoring. The system can ensure the steady transmission of droplets in long tubing without an external power source and generate stable droplets of suitable size for dPCR by two needles and a narrowed Teflon tube. The stable thermal cycle required by dPCR can be achieved by using only one constant temperature heater. In addition, our system has realized the real-time detection of droplet fluorescence in each thermal cycle, which makes up for the drawbacks of the end-point detection method used in traditional continuous-flow dPCR. This continuous-flow digital PCR by the compressed air-driven method can meet the requirements of droplet thermal cycle and diagnosis in a clinical-level serum sample. Comparing the detection results of clinical samples (hepatitis B virus serum) with commercial instruments (CFX Connect; Bio Rad, Hercules, CA, USA), the linear correlation reached 0.9995. Because the system greatly simplified the traditional dPCR process, this system is stable and user-friendly.

Detection of CTCs and CSCs in the staging and metastasis of non-small cell lung cancer based on microfluidic chip and the diagnostic significance.

Dynamic monitoring of CTCs/CSCs can assist in the diagnosis and prognosis of tumors. This study explores the diagnostic significance of microfluidic chip technology in the detection of CTCs/CSCs in clinical staging and metastasis of patients with non-small cell lung cancer (NSCLC). That lays a solid foundation for the use of microfluidic chips to monitor CTCs/CSCs for the stage and metastasis of patients with non-small cell lung cancer. This study collected 80 patients with lung cancer from October 2017 to October 2018. Meanwhile, 30 healthy people and 30 patients with benign lung diseases were selected during the same period as the control group 1 and the control group 2, respectively. CellSearch (Huntington Valley, PA, USA) and microfluidic chip were used to detect CTCs, the sensitivities were recorded. ELISA methods were used to detect the concentrations of tumor markers VEGF-C, CEA, and CA125 in serum, and their association with CTCs and CSCs was analyzed. In addition, after 3 months, we followed up 40 patients with lung cancer, recorded their prognosis, and extracted peripheral blood to detect changes in their CTCs and CSCs. The CellSearch (Huntington Valley, PA, USA) system and the microfluidic chip system were used to detect the CTCs in patients with lung cancer, and the sensitivity and specificity of the patients were analyzed. The changes in CTCs and CSCs in the peripheral blood of the patient were recorded. It can be seen that the positive rate of CTCs and CSCs is not significantly correlated with the patients' age, gender, pathological type (adenocarcinoma, squamous cell carcinoma), etc. They are significantly correlated with clinical stage (I + II and III + IV) and metastasis (metastasis and non-metastasis) (p<0.01). Then, we divided the patients into groups for testing, and analyzed the association between different groups of patients and CTCs and CSCs. Compared with control group 1 and control group 2, the positive rates of CTCs and CSCs in lung cancer metastasis group and non-metastasis group were significantly different (p<0.05). Compared with the control group 1 and control group 2, the positive rates of CTCs and CSCs in stage I + II and III + IV of lung cancer were significantly different (p<0.05). The positive rate was significantly higher in the cancer metastasis group (p<0.05). The concentrations of tumor markers VEGF-C, CEA, CA125 in the serum of patients were consistent with CTCs-negative and CTC-positive lung cancer, with significant differences (p<0.05). CSCs negative and CSCs positive patients have similar results. Subsequently, we analyzed the sensitivity and specificity of CSCs, CTCs, and tumor markers for the diagnosis of NSCLC. The results showed that the sensitivity of CSCs and CTCs to diagnose patients was significantly higher than that of tumor markers. This study shows that our microfluidic chip device can exhibit relatively good performance and can better detect CTCs and CSCs. Monitoring CTCs and CSCs of patients can provide a basis for judging the stage and metastasis of patients.

Droplet-based Synthesis of Homogeneous Gold Nanoparticles for Enhancing HRP-based ELISA Signals

Gold nanoparticles (AuNPs) have widely used for various biological applications, such as drug screening, photo-thermal therapy, and biosensing. In particular, the synthesis of AuNPs with narrow size distribution plays an important role in increasing the efficiency of nanoparticle-mediated biosensors. However, the conventional synthesis methods (e.g., citrate reduction method) still suffer from controlling the sizes of the nanoparticles. In this paper, we present the synthesis method of homogeneous AuNPs using a droplet-based microfluidic chip. Prior to experiments, we optimized the size of droplets using a simulation software for stable droplet generation. We demonstrated that the nanoparticles synthesized in our microfluidic chip system showed a narrower size distribution and a higher reproducibility compared to conventional batch synthesis. Furthermore, we observed that the signal of anti-horseradish peroxidase (HRP) was significantly enhanced by the droplet-based microfluidic chip. Therefore, our synthesis method of homogeneous AuNPs could play an important role in improving the efficiency of AuNPs-based sensing signals.

Modeling Pharmacokinetic Profiles for Assessment of Anti-Cancer Drug on a Microfluidic System.

The pharmacokinetic (PK) properties of drug, which include drug absorption and excretion, play an important role in determining the in vivo pharmaceutical activity. However, current in vitro systems that model PK profiles are often limited by the in vivo-like concentration profile of a drug. Herein, we present a perfused and multi-layered microfluidic chip system to model the PK profile of anti-cancer drug 5-FU in vitro. The chip device contains two layers of culture channels sandwiched by a porous membrane, which allows for drug exposure and diffusion between the two channels. The integration of upper intestine cells (Caco-2) and bottom targeted cells within the device enables the generation of loading and clearance portions of a PK curve under peristaltic flow. Fluorescein as a test molecule was initially used to generate a concentration-time curve, investigating the effects of parameters of flow rate, administration time, and initial concentration on dynamic drug concentration profiles. Furthermore, anti-cancer drug 5-FU was performed to assess its pharmaceutical activity on target cells (human lung adenocarcinoma cells or human pulmonary alveolar epithelial cells) using different drug administration regimens. A dynamic, in vivo-like 5-FU exposure refers to PK profile regimen, led to generate a lower drug concentration (dynamically fluctuate from 0 to 1 μg/mL affected by absorption) compared to the constant exposure. Moreover, the PK profile regimen alleviates the drug-induced cytotoxicity on target cells. These results demonstrate the feasibility of determining the PK profiles using this microfluidic system with in vivo-like drug administration regimens. This established system may provide a powerful platform for the prediction of drug safety and effectiveness in the pharmaceutical research.

On-Sensor Cryopreservation of Adherent Cells in Lab-on-a-Chip Systems

Introduction Biochemical sensors are one of the essential tools for cell-based assays used in major research fields including drug discovery, cancer research, and immunology. Although significant efforts have been made to develop new technologies and tools, most existing systems in this field are still not suitable for “ready‐to‐use in-field” applications, as the cells inside the assay need vital parameters, such as oxygen, nutrients, and temperature and therefore will not survive during a transportation to an end user. Nevertheless, providing these parameters is not practicable during conventional transportation either. Those systems need to be assembled and prepared on-site, which often requires a cell culture laboratory setting and trained staff. Thus, there is an urgent need for preserving the whole optimized assay system to utilize them for concepts like “ready-to-use” or “on-demand-use”.Cryopreservation, the process of freezing and preserving the cells at sub-zero temperatures is a well-known technique for cell culturing. It could be one possible solution to solve the transportation and storage challenges in the fields mentioned above. However, freezing of adherent cells is more prone to the cell membrane damage and cell detachment, due to ice crystal formation and a mismatch in the linear thermal expansion between the frozen cell membrane and the rigid substrate [1]. Therefore, innovative methods and tools must be implemented to overcome these challenges.In this work, for the first time, the surface of a field-effect-based sensor was modified with flexible electrospun fibers to allow on-sensor cryopreservation. Furthermore, a protocol was developed to freeze and to thaw adherent cells in a microfluidic channel. Method The light-addressable potentiometric sensor (LAPS), a field-effect-based biochemical sensor, can detect the extracellular acidification of the cells due to its pH sensitive transducer layer (Ta2O5). The LAPS was fabricated as a structure of Al/p-Si/SiO2/Ta2O5 as described in Ref. [2]. The sensor surface was modified with flexible polyethylene vinyl acetate (PEVA) fibers using an electrospinning method. The modified LAPS chip was then fixed to the underside of a bottomless microfluidic slide to form a miniaturized device (cryo-chip) (Figure 1(a) and (b)). A flexible polymer coverslip and a conventional LAPS were used as control samples. All samples were sterilized by 70% ethanol for one hour under aseptic conditions in a laminar flow cabinet to maintain the sterility. Chinese hamster ovary (CHO-K1) cells were adherently cultured inside the channels of the device with the mixture of Ham’s Nutrient Mixture F-12/Dulbecco’s Modified Eagle Medium (Ham’s F-12/DMEM, 1:2 mixture, pH 7) supplemented with 5% fetal calf serum (FCS), 100 U/ml penicillin and 100 mg/ml streptomycin. After the cell culture inside the channels were obtained for 48h under cell culture conditions in an incubator, the entire device was placed in a 3D-printed freezing container and frozen at -80oC using a cryoprotectant solution (90% fetal calf serum supplemented with 10% dimethyl sulfoxide). The samples were kept in the freezer overnight. The frozen device was then thawed rapidly by transferring them directly to the incubator (37oC). The cryoprotectant solution inside the channels was removed by washing with the fresh medium (37oC) four times, as soon as the ice crystals disappeared. Cell recovery and cell viability were analyzed before and after cryopreservation using a dye exclusion assay and a cell counting kit (CCK)-8 assay. In addition, as proof-of-concept measurements, the extracellular acidification of the cells was monitored by the LAPS chip, after the cryopreservation. Figure 1: Photos of the cryo-chip system for on-sensor cryopreservation. a) The modified LAPS chip integrated in a microfluidic chip system and its complementary connections; b) culturing of the CHO-K1 cells inside the channels on the LAPS surface, which are modified by electrospun PEVA fibers. Results and Conclusions The results showed that the sensor surface modified with the electrospun PEVA fibers exhibits enhanced biocompatibility, which promotes cell proliferation and spreading. In addition, the novel cryo-chip system using this hybrid structure (rigid/flexible) is effective compared to an un-modified LAPS surface for keeping cells viable during on-sensor cryopreservation. These findings showed, for the first time, that a cryopreservation on-chip is possible and that microfluidic systems including semiconductor based sensors can survive the cryopreservation treatment. Thus, this kind of cryo-chip systems enable on-sensor cryopreservation and measurement which can open up a new possibility for “ready-to-use, in field” applications. Being able to prepare the entire system at the manufacturing stage and to send them via a cold-chain transport further eliminate potential run-to-run and operator-to-operator variability, resulting in more reproducible results. Acknowledgements Dua Özsoylu (DÖ) would like to acknowledge the PhD research scholarship grant from Scientific and Technological Research Council of Turkey (TÜBITAK) under BIDEB 2214-A. The authors also gratefully thank the Federal Ministry of Education and Research of Germany (Opto-Switch FKZ: 13N12585). This study is a part of PhD thesis study of DÖ (thesis number DEU. HSI. PhD-2013970198) in Dokuz Eylül University, Institute of Health Sciences, Turkey.

Hollow hanging-core fiber SPR sensor for microfluidic chip with large size channel

We propose and demonstrate a surface plasmon resonance (SPR) sensor based on a hollow hanging-core fiber (HHCF). The diameter of the air hole in the HHCF is 130 μm, which ensures the infiltration of the liquid samples. We deposit the gold film on the surface of the hanging-core, and an evanescent field near the hanging-core will excite the SPR. The relationship between the gold film thickness and the testing sensitivity is studied. The experimental results show that the thicker the gold film, the longer the resonance wavelength, and the higher the testing sensitivity. The testing sensitivity is in the range of 1440 nm/RIU to 2010 nm/RIU, when the gold film thickness range is 30−70 nm with the sample refractive index range of 1.333−1.433. Due to the unique structure of the HHCF, the proposed SPR sensor has the advantage of being applied in a microfluidic chip system.

A lab-on-a-chip for rapid miRNA extraction.

We present a simple to operate microfluidic chip system that allows for the extraction of miRNAs from cells with minimal hands-on time. The chip integrates thermoelectric lysis (TEL) of cells with native gel-electrophoretic elution (GEE) of released nucleic acids and uses non-toxic reagents while requiring a sample volume of only 5 μl. These properties as well as the fast process duration of 180 seconds make the system an ideal candidate to be part of fully integrated point-of-care applications for e.g. the diagnosis of cancerous tissue. GEE was characterized in comparison to state-of-the-art silica column (SC) based RNA recovery using the mirVana kit (Ambion) as a reference. A synthetic miRNA (miR16) as well as a synthetic snoRNA (SNORD48) were subjected to both GEE and SC. Subsequent detection by stem-loop RT-qPCR demonstrated a higher yield for miRNA recovery by GEE. SnoRNA recovery performance was found to be equal for GEE and SC, indicating yield dependence on RNA length. Coupled operation of the chip (TEL + GEE) was characterized using serial dilutions of 5 to 500 MCF7 cancer cells in suspension. Samples were split and cells were subjected to either on-chip extraction or SC. Eluted miRNAs were then detected by stem-loop RT-qPCR without any further pre-processing. The extraction yield from cells was found to be up to ~200-fold higher for the chip system under non-denaturing conditions. The ratio of eluted miRNAs is shown to be dependent on the degree of complexation with miRNA associated proteins by comparing miRNAs purified by GEE from heat-shock and proteinase-K based lysis.

Automated microfluidic chip system for radiosynthesis of PET imaging probes.

Positron emission tomography (PET) is a powerful non-invasive molecular imaging technique for the early detection, characterization, and "real-time" monitoring of disease, and for investigating the efficacy of drugs (Phelps, 2000; Ametamey et al., 2008). The development of molecular probes bearing short-lived positron-emitting radionuclides, such as 18F (half-life 110 min) or 11C (half-life 20 min), is crucial for PET imaging to collect in vivo metabolic information in a time-efficient manner (Deng et al., 2019). In this regard, one of the main challenges is rapid synthesis of radiolabeled probes by introducing the radionuclides into pharmaceuticals as soon as possible before injection for a PET scan. Although many potential PET probes have been discovered, only a handful can satisfy the demand for a highly efficient synthesis procedure that achieves radiolabeling and delivery for imaging within 1-2 radioisotope half-lives. Only a few probes, such as 2-deoxy-2-[18F]fluoro-D-glucose (18F-FDG) and [18F]fluorodopa, are routinely produced on a commercial scale for daily clinical diagnosis (Grayson et al., 2018; Carollo et al., 2019).

Microfluidic chip system integrated with light addressable potentiometric sensor (LAPS) for real-time extracellular acidification detection

Metabolism is a common biological mechanism in living cells. Acidification plays an important role in cell metabolism, in which the extracellular pH change is used to indicate the vitality of cells. For extracellular detection of cell metabolic substances, light addressable potentiometric sensor (LAPS) has many advantages, such as high sensitivity, easy encapsulation, and convenient integration with microfluidic system for cell experiments. LAPS is a spatially resolved biochemical sensor based on field-effect. In this work, we present a microfluidic system integrated with LAPS for real-time extracellular acidification rate (ECAR) detection. The functions of traditional microphysiometer are achieved with simpler structure devices. Polydimethylsiloxane (PDMS) chamber was manufactured for cell culture, and microfluidic flow paths were used for medium and drug delivery. A bubble trap device was applied to eliminate air bubbles generated in microfluidics. Characteristic tests and cell metabolism experiments were carried out to determine the performance of LAPS by monitoring the pH change of hepatoma HepG2 cells. Glucose and doxorubicin were delivered to the cell chamber to verify the effects of the drug. The pH sensitivity of LAPS is 335.5 nA/pH at the working point in constant voltage mode. The ECAR of HepG2 cells was -48.53 mpH/min in normal glucose medium (25 mM), and it changed to -114.42 mpH/min in high glucose medium (125 mM) and -17.88 mpH/min under the effect of doxorubicin (10 μM). The results show that the microfluidic LAPS presents good performance in real-time detection of cell acidification and provides a convenient means of assessing cellular specificity of drugs. The modular structure and high expandability make the microfluidic LAPS has good potential in the application of organ-on-chip.

Temperature gap drives directed diffusion in microfluidic chip system

Diffusion plays a critical role in establishing functional bio/solid soft interfaces for bioassays, biosensors, and biofuel cells. An understanding of micro-diffusion near the interface is significant for developing high-performance bioassays, biosensors, and biofuel cells. Herein, we explored micro-diffusion behavior at different temperature gaps in microfluidic chip and enzyme-linked immunosorbent assay (ELISA) microplates. It exhibited that temperature gap could distinctly promote directional diffusion of molecules in microfluidic chip from high concentration zone to low concentration zone. In addition, experimental results of specially designed ELISA also partly confirmed that the temperature gap could effectively improve the performance of ELISA by 54.5%. In compared with conventional ELISA, the as-prepared temperature-gap functional module in microfluidic chip has obvious advantages of miniaturization, integration, customization, and low cost. All in all, the current work indicates that temperature-gap function has great potential in biomedical detection, food safety, and so on. It can be utilized to develop novel biological detection approaches and related instruments or microfluidic chips.