Bioelectronic properties of DNA, protein, cells and their applications for diagnostic medical devices

Electro-deformation spectroscopy: A unified method for simultaneous electrical and mechanical characterization of single cells

The intrinsic electrical and mechanical properties of cells are not only valuable biophysical markers reflective of physiological conditions but also play important roles in the development and progression of human diseases. Existing single-cell techniques are restricted to assessing either mechanical or electrical properties. We introduce the development of electro-deformation spectroscopy (EDS), namely the frequency-dependent electro-deformation, as a new method for simultaneous electrical and mechanical characterization of individual cells in suspension. To facilitate the practical use of this technology, we developed a testing procedure that evaluates red blood cells (RBCs) directly from whole blood in a simple microfluidic system, employing an electric field magnitude of 34 kV/m over a frequency range of 15 MHz to 100 kHz. The EDS measurement is performed under stationary conditions without special cell stabilization, at a moderate throughput of 50-100 cells per minute. We develop an experimental-computational framework to decouple cell electromechanics by optimizing the most suitable parameters of the relative permittivity of cell membrane, cytoplasm electrical conductivity, and membrane shear modulus. This technique, tested on RBCs from 4 healthy human samples, revealed membrane relative permittivity of 3.6 - 5.8, membrane shear modulus of 2.2 - 2.8 µN/m, and cytoplasm conductivity of 0.47 - 0.81 S/m. EDS analysis identifies the marked intrasample heterogeneity and individual variability in both cellular electrical and mechanical properties. The EDS framework can be readily used to test RBCs across different species, pathological states, and other cell types of similar structures as RBCs. STATEMENT OF SIGNIFICANCE: This work introduces electro-deformation spectroscopy (EDS) as a unified method for simultaneous electrical and mechanical characterization of single cells in suspension. This is the first-of-its-kind technology for such purposes. EDS can be performed in a simple microfluidic system with minimal sample preparation, making it a convenient and powerful tool for label-free, non-invasive single-cell analysis. We validate the applicability of EDS by measuring the intrasample heterogeneity and individual variability based on the electromechanical parameters of interest for human red blood cells. Single-cell EDS has the potential to enable rapid and reliable detection of cellular changes by diseases or drug treatments and provide insights into the fundamental bioelectromechanical mechanisms of cellular adaptation and dysfunction. This work advances the field of single-cell analysis and contributes to the development of biomaterials and biotechnologies based on cellular electromechanics.

How to make DNA data storage more applicable

The storage of digital data is becoming a worldwide problem. DNA has been recognized as a biological solution due to its ability to store genetic information without alteration over long periods. The first demonstrations of high-capacity long-lasting DNA digital data storage have been shown. However, high storage costs and slow retrieval of the data must be overcome to make DNA data storage more applicable and marketable. Herein, we discuss the issues and recent advances in DNA data storage methods and highlight pathways to make this technology more applicable to real-world digital data storage. We envision that a combination of molecular biology, nanotechnology, novel polymers, electronics, and automation with systematic development will allow DNA data storage sufficient for everyday use.

Recent Advances in Clustered Regularly Interspaced Short Palindromic Repeats-Based Biosensors for Point-of-Care Pathogen Detection

Infectious pathogens are pressing concerns due to their heavy toll on global health and socioeconomic infrastructure. Rapid, sensitive, and specific pathogen detection methods are needed more than ever to control disease spreading. The fast evolution of clustered regularly interspaced short palindromic repeats (CRISPR)-based diagnostics (CRISPR-Dx) has opened a new horizon in the field of molecular diagnostics. This review highlights recent efforts in configuring CRISPR technology as an efficient diagnostic tool for pathogen detection. It starts with a brief introduction of different CRISPR-Cas effectors and their working principles for disease diagnosis. It then focuses on the evolution of laboratory-based CRISPR technology toward a potential point-of-care test, including the development of new signaling mechanisms, elimination of preamplification and sample pretreatment steps, and miniaturization of CRISPR reactions on digital assay chips and lateral flow devices. In addition, promising examples of CRISPR-Dx for pathogen detection in various real samples, such as blood, saliva, nasal swab, plant, and food samples, are highlighted. Finally, the challenges and perspectives of future development of CRISPR-Dx for infectious disease monitoring are discussed.

Conductive Materials with Elaborate Micro/Nanostructures for Bioelectronics

Bioelectronics, an emerging field with the mutual penetration of biological systems and electronic sciences, allows the quantitative analysis of complicated biosignals together with the dynamic regulation of fateful biological functions. In this area, the development of conductive materials with elaborate micro/nanostructures has been of great significance to the improvement of high-performance bioelectronic devices. Thus, here, a comprehensive and up-to-date summary of relevant research studies on the fabrication and properties of conductive materials with micro/nanostructures and their promising applications and future opportunities in bioelectronic applications is presented. In addition, a critical analysis of the current opportunities and challenges regarding the future developments of conductive materials with elaborate micro/nanostructures for bioelectronic applications is also presented.

Laser ablative TiO2 and tremella-like CuInS2 nanocomposites for robust and ultrasensitive photoelectrochemical sensing of let-7a

A photoelectrochemical (PEC) biosensor based on a multiple signal amplification strategy was established for highly sensitive detection of microRNA (miRNA). TiO₂ was prepared on the surface of titanium sheet by laser etching to improve its stability and photoelectrical properties, and CuInS₂-sensitized TiO₂ was used to form a superior photoelectrical layer, which realized the initial signal amplification. The electron donor dopamine (DA) was modified to H2 as a signal regulator, which effectively increased the photocurrent signal. To further amplify the signal, an enzyme-free hybridization reaction was implemented. When target let-7a and fuel-DNA (F-DNA) were present, the base of H1 specifically recognized let-7a and forced dopamine@AuNPs-H2 away from the electrode surface. Subsequently, the end base of H1 specifically recognized F-DNA, and let-7a was replaced and recycled to participate in the next cycle. Enzyme-free circulation, as a multifunctional amplification method, ensured the recycling of target molecules. This PEC sensor for let-7a detection showed an excellent linear response from 0.5 to 1000 pM with a detection limit of 0.12 pM. The intra-batch RSD was 3.8% and the recovery was 87.74-108.1%. The sensor was further used for clinical biomolecular monitoring of miRNA, showing excellent quantitative detection capability.

CRISPR-Cas based virus detection: Recent advances and perspectives

Viral infections are one of the most intimidating threats to human beings. One convincing example is the coronavirus disease 2019 (COVID-19) caused by SARS-CoV-2. Rapid, sensitive, specific and field-deployable identification of causal viruses is critical for disease surveillance, control and treatment. The shortcomings of current methods create an impending need for developing novel biosensing platforms. CRISPR-Cas systems, especially CRISPR-Cas12a and CRISPR-Cas13a, characterized by their sensitivity, specificity, high base resolution and programmability upon nucleic acid recognition, have been repurposed for molecular diagnostics, surging a new path forward in biosensing. They, as the core of some robust diagnostic tools, are revolutionizing the way that virus can be detected. This review focuses on recent advances in virus detection with CRISPR-Cas systems especially CRISPR-Cas12a/Cas13a. We started with a short introduction to CRISPR-Cas systems and the properties of Cas12a and Cas13a effectors, and continued with reviewing the current advances of virus detection utilizing CRISPR-Cas systems. The significance and advantages of such methods were then discussed. Finally, the challenges and perspectives were proposed. We tried to provide readers with a concise profile of emerging and fast-expanding CRISPR-Cas based biosensing technology, and highlighted its potential applications in a range of scenarios with regard to virus detection.