Real-time monitoring of DNA immobilization and detection of DNA polymerase activity by a microfluidic nanoplasmonic platform

Viral infection is one of the leading causes of mortality worldwide. The growth of globalization significantly increases the risk of virus spreading, making it a global threat to future public health. In particular, the ongoing coronavirus disease 2019 (COVID‐19) pandemic outbreak emphasizes the importance of devices and methods for rapid, sensitive, and cost‐effective diagnosis of viral infections in the early stages by which their quick and global spread can be controlled. Micro and nanoscale technologies have attracted tremendous attention in recent years for a variety of medical and biological applications, especially in developing diagnostic platforms for rapid and accurate detection of viral diseases. This review addresses advances of microneedles, microchip‐based integrated platforms, and nano‐ and microparticles for sampling, sample processing, enrichment, amplification, and detection of viral particles and antigens related to the diagnosis of viral diseases. Additionally, methods for the fabrication of microchip‐based devices and commercially used devices are described. Finally, challenges and prospects on the development of micro and nanotechnologies for the early diagnosis of viral diseases are highlighted.

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Section: Detection Techniquesmentioning

confidence: 99%

Micro and Nanoscale Technologies for Diagnosis of Viral Infections

Nasrollahi

Haghniaz

Hosseini

et al. 2021

Small

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“…Structure/orientation 54,55,76 Complement selectivity 52 Aptamer selectivity [70][71][72] Enzymatic activity [73][74][75] Cell layers Mechanical/rheological properties 17 Adhesion kinetics 38,39,42,43 Cytoskeletal changes 47,48 Apoptosis 49 Oncogenesis 50 into a continuous film depending on the concentration, surface hydration, and particle composition (Figure 2(a) to (c)). Tajik-Ahmadabad et al similarly assessed the deposition of lipid nanoparticles meant for the delivery of siRNA.…”

Section: Nucleic Acid Biopolymersmentioning

confidence: 99%

“…Template directed DNA synthesis with polymerase enzymes has been studied on QCM-D sensors to reveal the time-dependent increases in layer thickness and changes in viscosity and shear modulus of the layer during polymerization. [73][74][75] Mechanical changes have also been observed while operating novel, tetrahedral nucleic acid nanopumps. 76 These pumps were self-assembled using complementary oligonucleotides and stably coupled to a gold QCM-D sensor through a thiol linker.…”

Section: The Role Of Qcm-d In Biosensingmentioning

confidence: 99%

Recent applications of QCM-D for the design, synthesis, and characterization of bioactive materials

Mosley

Talarico

Byrne

2021

Journal of Bioactive and Compatible Polymers

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The clinical translation of bioactive technologies is lacking compared to the number of novel technologies reported in the literature. This is in part due to the difficulties in characterizing bioactive materials to understand and predict their biological response. To progress the field and increase clinical success, more robust analytical techniques must be utilized when investigating novel bioactive materials. The quartz crystal microbalance with dissipation (QCM-D), a label-free sensing instrument based on an acoustic resonator, is used to quantify mass change and viscoelastic parameters from soft materials at the nanoscale, in situ, with precise temporal resolution and operation in both liquid and gaseous environments. The versatility of QCM-D has enhanced the characterization of bioactive polymers and sensing arrays for advanced applications of novel biotechnologies. In this review, we highlight exciting, recent applications of QCM-D for the investigation of bioactive materials. Attention is given to the dynamic mechanical properties of bioactive materials, discerning protein structure on surfaces, probing cell adhesion and cytoskeletal changes, and biosensing applications. We conclude that QCM-D has untapped utility in the pre-clinical investigation of bioactive materials and further utilization can improve the clinical success of novel technologies.

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“…Thermal cycler-free PCR can also be conducted in a microfluidic chip by alternately flowing the fluid across hot and cold regions 12 . In addition to on-chip amplification, recently developed microfluidic devices have also been integrated with highly sensitive sensing platforms such as nano-plasmonic sensors, electrochemical sensors, and terahertz spectroscopy, enabling rapid and accurate NA identification 13 - 15 . However, the multifunctionality built into a single chip often requires multichambers and sophisticated fluidic controls; these present a major technical obstacle to mass-producing devices, particularly via injection molding in plastics, for commercialization.…”

Section: Introductionmentioning

confidence: 99%

Rapid and simple single-chamber nucleic acid detection system prepared through nature-inspired surface engineering

et al. 2021

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Background: Nucleic acid (NA)-based diagnostics enable a rapid response to various diseases, but current techniques often require multiple labor-intensive steps, which is a major obstacle to successful translation to a clinical setting. Methods: We report on a surface-engineered single-chamber device for NA extraction and in situ amplification without sample transfer. Our system has two reaction sites: a NA extraction chamber whose surface is patterned with micropillars and a reaction chamber filled with reagents for in situ polymerase-based NA amplification. These two sites are integrated in a single microfluidic device; we applied plastic injection molding for cost-effective, mass-production of the designed device. The micropillars were chemically activated via a nature-inspired silica coating to possess a specific affinity to NA. Results: As a proof-of-concept, a colorimetric pH indicator was coupled to the on-chip analysis of NA for the rapid and convenient detection of pathogens. The NA enrichment efficiency was dependent on the lysate incubation time, as diffusion controls the NA contact with the engineered surface. We could detect down to 1×10 3 CFU by the naked eye within one hour of the total assay time. Conclusion: We anticipate that the surface engineering technique for NA enrichment could be easily integrated as a part of various types of microfluidic chips for rapid and convenient nucleic acid-based diagnostics.

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Real-time monitoring of DNA immobilization and detection of DNA polymerase activity by a microfluidic nanoplasmonic platform

Cited by 54 publications

References 31 publications

Micro and Nanoscale Technologies for Diagnosis of Viral Infections

Micro and Nanoscale Technologies for Diagnosis of Viral Infections

Recent applications of QCM-D for the design, synthesis, and characterization of bioactive materials

Rapid and simple single-chamber nucleic acid detection system prepared through nature-inspired surface engineering

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