Highly sensitive and multiplexed one-step RT-qPCR for profiling genes involved in the circadian rhythm using microparticles.

Given the growing interest in molecular diagnosis, highly extensive and selective detection of genetic targets from a very limited amount of samples is in high demand. We demonstrated the highly sensitive and multiplexed one-step RT-qPCR platform for RNA analysis using microparticles as individual reactors. Those particles are equipped with a controlled release system of thermo-responsive materials, and are able to capture RNA targets inside. The particle-based assay can successfully quantify multiple target RNAs from only 200 pg of total RNA. The assay can also quantify target RNAs from a single cell with the aid of a pre-concentration process. We carried out 8-plex one-step RT-qPCR using tens of microparticles, which allowed extensive mRNA profiling. The circadian cycles were shown by the multiplex one-step RT-qPCR in human cell and human hair follicles. Reliable 24-plex one-step RT-qPCR was developed using a single operation in a PCR chip without any loss of performance (i.e., selectivity and sensitivity), even from a single hair. Many other disease-related transcripts can be monitored using this versatile platform. It can also be used non-invasively for samples obtained in clinics.

In-particle stem-loop RT-qPCR for specific and multiplex microRNA profiling.

Here we report a novel method of microRNA (miRNA) profiling with particle-based multiplex quantitative reverse transcription polymerase chain reaction (RT-qPCR). To achieve target-specific reaction in a particle, the stem-loop RT primer and forward primer for each target miRNA were chemically immobilized to the particle. Target-specific cDNA synthesis proceeds with the stem-loop RT primer and then qPCR subsequently proceeds with the forward primer to rapidly achieve a quantitative result. High-fidelity multiplex assay was also accomplished in a single PCR process by loading multiple particles for each specific miRNA. The method for primer supply in the particles, involving confinement of the target-specific RT and PCR primers in the matrix of particles, led to the reduction of nonspecific reactions and improved the selectivity of the miRNA assay while minimizing labor in a multiple target assay. Specifically, this particle-based assay enabled the differentiation of mature miRNA from precursor with selectivity of 270:1 in terms of amplification speed. This advanced method also showed good discrimination among highly homologous let-7 family members, with cross-reaction rates of less than 5%. We demonstrated a very simple process of five-plex miRNA profiling in total RNA, and the measured changes in expression level were consistent with those from a conventional singleplex method.

Thermo-Responsive Polymer Capsules in Real-Time One-Step RT-PCR for Highly Multiplex RNA Analysis.

Rapid and simple detection of RNA targets is in high demand due to the growing threat of pandemic viruses. One-step real-time, reverse transcription-polymerase chain reaction (One-step RT-qPCR) using a controlled release system of thermo-responsive materials is developed in this paper to enable high-fidelity RNA analysis as suppressing by-products. The nanocapsules, consisting of upper critical solution temperature (UCST) material and PCR primers, carry or release the primers depending upon the temperature. The UCST nanocapsules are introduced into hydrogel microparticles incorporated with RT primers and then the target RNA is selectively amplified in the microparticle through one-step RT-qPCR. Severe side products are sharply subdued by separating the PCR primers from the RT process by means of the microparticles with nanocapsules. Because the one-step assay is now implemented in a single microparticle, multiple target RNAs can be analyzed in a simple RT-qPCR of multiple particles. Reliable 18-plex one-step RT-qPCR is successfully conducted within 30 min using single-color fluorescent optics. This work also explains the facile fabrication processes used for the thermo-responsive nanocapsules and hydrogel microparticles by the blending polymerization method. Extensible multiplex analysis of influenza virus demonstrates the versatile uses of this one-step RT-qPCR platform.

Automated accurate lumen segmentation using L-mode interpolation for three-dimensional intravascular optical coherence tomography.

Intravascular optical coherence tomography (IVOCT) lumen-based computational flow dynamics (CFD) enables physiologic evaluations such as of the fractional flow reserve (FFR) and wall sheer stress. In this study, we developed an accurate, time-efficient method for extracting lumen contours of the coronary artery. The contours of cross-sectional images containing wide intimal discontinuities due to guide wire shadowing and large bifurcations were delineated by utilizing the natural longitudinal lumen continuity of the arteries. Our algorithm was applied to 5931 pre-intervention OCT images acquired from 40 patients. For a quantitative comparison, the images were also processed through manual segmentation (the reference standard) and automated ones utilizing cross-sectional and longitudinal continuities. The results showed that the proposed algorithm outperforms other schemes, exhibiting a strong correlation (R = 0.988) and overlapping and non-overlapping area ratios of 0.931 and 0.101, respectively. To examine the accuracy of the OCT-derived FFR calculated using the proposed scheme, a CFD simulation of a three-dimensional coronary geometry was performed. The strong correlation with a manual lumen-derived FFR (R = 0.978) further demonstrated the reliability and accuracy of our algorithm with potential applications in clinical settings.

Multiplex real-time PCR using temperature sensitive primer-supplying hydrogel particles and its application for malaria species identification.

Real-time PCR, also called quantitative PCR (qPCR), has been powerful analytical tool for detection of nucleic acids since it developed. Not only for biological research but also for diagnostic needs, qPCR technique requires capacity to detect multiple genes in recent years. Solid phase PCR (SP-PCR) where one or two directional primers are immobilized on solid substrates could analyze multiplex genetic targets. However, conventional SP-PCR was subjected to restriction of application for lack of PCR efficiency and quantitative resolution. Here we introduce an advanced qPCR with primer-incorporated network (PIN). One directional primers are immobilized in the porous hydrogel particle by covalent bond and the other direction of primers are temporarily immobilized at so-called 'Supplimers'. Supplimers released the primers to aqueous phase in the hydrogel at the thermal cycling of PCR. It induced the high PCR efficiency over 92% with high reliability. It reduced the formation of primer dimers and improved the selectivity of qPCR thanks to the strategy of 'right primers supplied to right place only'. By conducting a six-plex qPCR of 30 minutes, we analyzed DNA samples originated from malaria patients and successfully identified malaria species in a single reaction.

Hydrogel micropost-based qPCR for multiplex detection of miRNAs associated with Alzheimer's disease.

Quantitative polymerase chain reaction (qPCR) renders profiling of genes of interest less time-consuming and cost-effective. Recently, multiplex profiling of miRNAs has enabled identifying or investigating predominant miRNAs for various diseases such as cancers and neurodegenerative diseases. Conventional multiplex qPCR technologies mostly use colorimetric measurements in solution phase, yet not only suffer from limited multiplexing capacity but also require target-screening processes due to non-specific binding between targets and primers. Here, we present hydrogel micropost-based qPCR for multiplex detection of miRNAs associated with Alzheimer's disease (AD). Our methodology promises two key advantages compared with the conventional solution-based PCR: 1) nearly no non-specific crosstalks between targets and primers, and 2) practically valuable multiplexing by spatial encoding within a single microchamber. Specifically, we immobilized hydrogel microposts (~ 400µm in diameter) within commercially available polycarbonate PCR chips by multi-step ultraviolet (UV, 365nm) exposure. We optimized this photoimmobilization for thermal cycles of PCR as well. Acrylated forward primers incorporated in polyethylene glycol diacrylate (PEGDA) posts played a crucial role to confine fluorescent signal of cDNA amplification within the PEGDA hydrogel. To demonstrate the potential of our platform, we successfully verified multiplex detection of five miRNAs, which were reported to be highly correlated with AD, from a complex buffer of human plasma.

Extensible multiplex real-time PCR for rapid bacterial identification with carbon nanotube composite microparticles.

The early diagnosis of pathogenic bacteria is significant for bacterial identification and antibiotic resistance. Implementing rapid, sensitive, and specific detection, molecular diagnosis has been considered complementary to the conventional bacterial culture. Composite microparticles of a primer-immobilized network (cPIN) are developed for multiplex detection of pathogenic bacteria with real-time polymerase chain reaction (qPCR). A pair of specific primers are incorporated and stably conserved in a cPIN particle. One primer is crosslinked to the polymer network, and the other is bound to carbon nanotubes (CNTs) in the particle. At the initiation of qPCR, the latter primer is released from the CNTs and participates in the amplification. The amplification efficiency of this cPIN qPCR is estimated at more than 90% with suppressed non-specific signals from complex samples. In multiplexing, four infective pathogens are successfully discriminated using this cPIN qPCR. Multiplex qPCR conforms with the corresponding singleplex assays, proving independent amplification in each particle. Four bacterial targets from clinical samples are differentially analyzed in 30min of a single qPCR trial with multiple cPIN particles.

Extensible Multiplex Real-time PCR of MicroRNA Using Microparticles.

Multiplex quantitative real-time PCR (qPCR), which measures multiple DNAs in a given sample, has received significant attention as a mean of verifying the rapidly increasing genetic targets of interest in single phenotype. Here we suggest a readily extensible qPCR for the expression analysis of multiple microRNA (miRNA) targets using microparticles of primer-immobilized networks as discrete reactors. Individual particles, 200~500 µm in diameter, are identified by two-dimensional codes engraved into the particles and the non-fluorescent encoding allows high-fidelity acquisition of signal in real-time PCR. During the course of PCR, the amplicons accumulate in the volume of the particles with high reliability and amplification efficiency over 95%. In a quick assay comprising of tens of particles holding different primers, each particle brings the independent real-time amplification curve representing the quantitative information of each target. Limited amount of sample was analyzed simultaneously in single chamber through this highly multiplexed qPCR; 10 kinds of miRNAs from purified extracellular vesicles (EVs).