Regular Glass Slides Research Articles

Label-free SARS-CoV-2 detection and classification using phase imaging with computational specificity

Efforts to mitigate the COVID-19 crisis revealed that fast, accurate, and scalable testing is crucial for curbing the current impact and that of future pandemics. We propose an optical method for directly imaging unlabeled viral particles and using deep learning for detection and classification. An ultrasensitive interferometric method was used to image four virus types with nanoscale optical path-length sensitivity. Pairing these data with fluorescence images for ground truth, we trained semantic segmentation models based on U-Net, a particular type of convolutional neural network. The trained network was applied to classify the viruses from the interferometric images only, containing simultaneously SARS-CoV-2, H1N1 (influenza-A virus), HAdV (adenovirus), and ZIKV (Zika virus). Remarkably, due to the nanoscale sensitivity in the input data, the neural network was able to identify SARS-CoV-2 vs. the other viruses with 96% accuracy. The inference time for each image is 60 ms, on a common graphic-processing unit. This approach of directly imaging unlabeled viral particles may provide an extremely fast test, of less than a minute per patient. As the imaging instrument operates on regular glass slides, we envision this method as potentially testing on patient breath condensates. The necessary high throughput can be achieved by translating concepts from digital pathology, where a microscope can scan hundreds of slides automatically.

Rare-Earth Doping Graphitic Carbon Nitride Endows Distinctive Multiple Emissions with Large Stokes Shifts

Rare-Earth Doping Graphitic Carbon Nitride Endows Distinctive Multiple Emissions with Large Stokes Shifts

Microfluidic diatomite analytical devices for illicit drug sensing with ppb-Level sensitivity

The escalating research interests in porous media microfluidics, such as microfluidic paper-based analytical devices, have fostered a new spectrum of biomedical devices for point-of-care (POC) diagnosis and biosensing. In this paper, we report microfluidic diatomite analytical devices (μDADs), which consist of highly porous photonic crystal biosilica channels, as an innovative lab-on-a-chip platform to detect illicit drugs. The μDADs in this work are fabricated by spin-coating and tape-stripping diatomaceous earth on regular glass slides with cross section of 400 × 30 μm2. As the most unique feature, our μDADs can simultaneously perform on-chip chromatography to separate small molecules from complex biofluidic samples and acquire the surface-enhanced Raman scattering spectra of the target chemicals with high specificity. Owing to the ultra-small dimension of the diatomite microfluidic channels and the photonic crystal effect from the fossilized diatom frustules, we demonstrate unprecedented sensitivity down to part-per-billion (ppb) level when detecting pyrene (1ppb) from mixed sample with Raman dye and cocaine (10 ppb) from human plasma. This pioneering work proves the exclusive advantage of μDADs as emerging microfluidic devices for chemical and biomedical sensing, especially for POC drug screening.

Tunable Plasmonic Silver Nanodomes for Surface-Enhanced Raman Scattering

Surface-enhanced Raman scattering (SERS) is an emerging analytical method used in biological and non-biological structure characterization. Since the nanostructure plasmonic properties is a significant factor for SERS performance, nanostructure fabrication with tunable plasmonic properties are crucial in SERS studies. In this study, a novel method for fabrication of tunable plasmonic silver nanodomes (AgNDs) is presented. The convective-assembly method is preferred for the deposition of latex particles uniformly on a regular glass slide and used as a template for polydimethylsiloxane (PDMS) to prepare nanovoids on a PDMS surface. The obtained nanovoids on the PDMS are used as a mold for AgNDs fabrication. The nanovoids are filled with Ag deposition by the electrochemical method to obtain metallic AgNDs. Scanning electron microscopy (SEM) and atomic force microscopy (AFM) are used for characterization of the structural properties of all fabricated AgNDs. The optical properties of AgNDs are characterized with the evaluation of SERS activity of 4-aminothiphonel and rhodamine 6G. In addition to experimental characterizations, the finite difference time domain (FDTD) method is used for the theoretical plasmonic properties calculation of the AgNDs. The experimental and theoretical results show that the SERS performance of AgNDs is strongly dependent on the heights and diameters of the AgNDs.

The role of substrates and environment in piezoresponse force microscopy: A case study with regular glass slides

Piezoresponse force microscopy (PFM) is a powerful tool for probing nanometer-scale ferroelectric and piezoelectric properties. Hysteretic switching of the phase and amplitude of the PFM response are believed to be the hallmark of ferroelectric and piezoelectric behavior respectively. However, the application of PFM is limited by the fact that similar hysteretic effects may also arise from mechanisms not related to ferroelectricity or piezoelectricity. In this paper we report our studies on regular glass slides that show ferroelectric-like signal without being ferroelectric and frequently used as a substrate in PFM experiments. We demonstrate how the substrates and other environmental factors like relative humidity and experimental conditions may influence the PFM results on novel materials.

Inkjet-Print Micromagnet Array on Glass Slides for Immunomagnetic Enrichment of Circulating Tumor Cells.

We report an inkjet-printed microscale magnetic structure that can be integrated on regular glass slides for the immunomagnetic screening of rare circulating tumor cells (CTCs). CTCs detach from the primary tumor site, circulate with the bloodstream, and initiate the cancer metastasis process. Therefore, a liquid biopsy in the form of capturing and analyzing CTCs may provide key information for cancer prognosis and diagnosis. Inkjet printing technology provides a non-contact, layer-by-layer and mask-less approach to deposit defined magnetic patterns on an arbitrary substrate. Such thin film patterns, when placed in an external magnetic field, significantly enhance the attractive force in the near-field close to the CTCs to facilitate the separation. We demonstrated the efficacy of the inkjet-print micromagnet array integrated immunomagnetic assay in separating COLO205 (human colorectal cancer cell line) from whole blood samples. The micromagnets increased the capture efficiency by 26% compared with using plain glass slide as the substrate.

Quantitative Assessment of Liver Steatosis on Tissue Section Using Infrared Spectroscopy

Quantitative Assessment of Liver Steatosis on Tissue Section Using Infrared Spectroscopy

Detecting Microparticles in Human Intestine with Synchrotron Based X-Ray Beamline

Purpose: Microparticles (MP) are non-biological inorganic bacterial-sized particles (0.1-0.7μm) from endogenous formation (calcium phosphate) or dietary intake (AlSi and Ti02), which may contribute to the pathogenesis of inflammatory bowel disease (IBD). This study was to establish the method for MP detection in human intestine.Methods: Biopsy tissue samples were collected from 5 IBD and 5 cancer screening patients undergoing colonoscopy.Tissue sections were cut at variable thickness (5, 10 and 20 um) prior to analysis on the Very Sensitive Elemental and Structural Probe Employing Radiation from a Synchrotron (VESPERS) microprobe beamline at the Canadian Light Source. They were mapped with micro-X-ray fluorescence spectroscopy to determine the spatial location of the MPs at an X-ray excitation energy of 13 keV. The beam had a spot size of 4 μm with an 8 μm step-size and 15 second dwell time. Tested sample conditions include formalin fixation, section thickness, mounting substrate (regular glass slide and Lexan film), and embedding medium (OCT).Results: Randomly selected areas in the mucosa or submucosa were observed. There was significant contamination in formalin-fixed tissue samples causing non-specific background. VESPERS exhibited greatest sensitivity with tissue sections of 20 um in thickness and demonstrated the best signal versus noise ratio. Specific signals of MPs from samples on Lexan film were much better with relatively lower background than those on glass slide. The OCT was free of contamination.Conclusion: Synchrotron-based X-ray microprobe techniques can be used for detecting and mapping MPs in normal and IBD affected human intestine. This will allow us further elucidation of the immunopathological role of MPs in IBD patients. Frozen fresh tissue sections of 20 um thickness mounted on Lexan film is the superior method of sample processing.

Detecting Microparticles in Human Intestine in Patients with Inflammatory Bowel Disease with Synchrotron Based X-ray Beamline

Purpose: Microparticles (MP) are non-biological inorganic bacterial-sized particles (0.1-0.7 μm) resulting from endogenous formation (calcium phosphate) or dietary intake (AlSi and Ti02). MPs may contribute to the pathogenesis of inflammatory bowel disease (IBD). To elucidate the actual role of MPs in IBD, it is important to directly evaluate the quantity and distribution of MPs at the cellular or sub cellular level in diseased and normal intestinal tissues, particularly the M-cell rich lymphoid aggregates (Peyer's patches), the major sites of MP entry into intestinal tissue. The aim of this study was to establish the method for MP detection in human intestinal tissue. Methods: Intestinal biopsy tissue samples were collected from 5 IBD and 5 colorectal cancer screening patients undergoing colonoscopy. Tissue sections were cut at variable thickness (5, 10 and 20 um) prior to analysis on the Very Sensitive Elemental and Structural Probe Employing Radiation from a Synchrotron (VESPERS) microprobe beamline at the Canadian Light Source (CLS). Tissue sections were mapped with micro-X-ray fluorescence (μXRF) spectroscopy in order to determine the spatial location of the MPs at an X-ray excitation energy of 13 keV. The X-ray beam had a spot size of 4 μm with an 8 μm step-size and 15 second dwell time. More in-depth chemical and structural analysis were performed on regions of interest in the XRF maps by micro-X-ray Diffraction (μXRD) and micro- X-ray absorption near-edge structure (μXANES) spectroscopy. Sample conditions that may have affected the results include formalin fixation, tissue section thickness, and the contents of the mounting substrate (regular glass slide and Lexan film) and embedding medium (OCT). This study was approved by Biomedical Research Ethics Board of University of Saskatchewan. Results: Randomly selected areas in the mucosa or submucosa were observed. There was significant contamination in formalin-fixed tissue samples resulting in a non specific background. VESPERS exhibited greatest sensitivity with tissue sections of 20 um in thickness and demonstrated the best signal versus noise ratio vs. 5 or 10 um thickness. Specific signals of Ti and Si from samples mounted on Lexan film were much better with relatively lower background than those on regular glass slide. The OCT was free of contamination. Conclusion: Synchrotron-based X-ray microprobe techniques can be used for detecting and mapping MPs in normal and IBD affected human intestine. This will allow us further elucidation of the immunopathological role of MPs in IBD patients. Frozen fresh tissue sections of 20 um thickness mounted on Lexan film is the superior method of sample processing.

Correction to Electrical Readout of Protein Microarrays on Regular Glass Slides

Correction to Electrical Readout of Protein Microarrays on Regular Glass Slides

Overcoming mass transport limitations to achieve femtomolar detection limits on silicon protein microarrays

Here we combine the use of fluorescence-enhancing silicon substrates coated by copoly(DMA–NAS–MAPS), a ter-copolymer based on N,N-dimethylacrylamide (DMA), N-acryloyloxysuccinimide (NAS), and 3-(trimethoxysilyl)propyl-methacrylate (MAPS), with an efficient dynamic incubation to overcome mass transport limitations and obtain femtomolar limits of detection. The high sensitivity was obtained with a conventional microarray scanner without the use of any sophisticated detection strategy or protocol. When the method was applied, an improvement of the analytical sensitivity of approximately three orders of magnitude was achieved for antibody detection when compared with the same assay performed on regular glass slides and static conditions. Moreover, limits of detection of 45 and 54pg/ml were obtained for hepatitis B superficial antigen and HIV p24 antigen, respectively.

Electrical Readout of Protein Microarrays on Regular Glass Slides

A new approach for the electrical readout of microarrays prepared on regular glass slides, using an array of impedimetric transducers (interdigitated electrodes, IDEs) is presented in this work. Impedance detection relies on the use of a urease-labeled immunoassay scheme. Urease is able to produce an increase in conductivity by hydrolysis of the urea substrate, which is measured with the IDEs and directly related to the amount of target analyte. Unlike previous electrical microarrays, the assay does not take place on top of the transducers but on a regular glass slide, which may enable the development of compact multiplexed analytical systems with lower cost per assay. A droplet of solution with the enzymatic substrate is deposited on each transducer of the array, and the microarray is positioned at a short distance (300 μm) so that each droplet wets one transducer and one spot of the microarray. This procedure allows reusing the transducer array for readout of a virtually unlimited number of microarrays. A microarray based on an immunoassay for the detection of a mouse generic protein in a concentration range from 0.03 to 30 μg mL(-1) was carried out to assess the performance of the electrical readout approach. A sigmoid response with a limit of detection of 0.1 μg mL(-1) and a dynamic range of 1 order of magnitude was obtained. A comparative study was also carried out with two well established analytical procedures. First, the urease-based immunoassay was tested in a 96 well microtiter plate using phenol red pH indicator and absorbance detection. Second, the microarray was carried out using the same target protein concentration range but applying a Cy3 label and fluorescence detection. Both assays allowed for the validation of the performance of the presented electrical readout system.

Zona thinning: ‘Laying it on thick’

The zona pellucida is a multi-layered glycoprotein coat surrounding the mammalian egg and embryo. To implant successfully in the uterine wall, the embryo must shed this coat. During human IVF, two approaches have been used to facilitate this event in order to enhance implantation: (I) breaching the zona pellucida entirely (assisted hatching) and (II) removing a limited stretch of the outermost layer (zona thinning). It is important to distinguish between these two approaches since the outermost layer of the human zona pellucida appears less hardened than the inner layers. In this issue of Reproductive BioMedicine Online, Valojerdi and co-workers from Tehran (Iran) report on detrimental effects of a rather vigorous method of zona pellucida thinning using a laser along one quarter of the embryo’s circumference. This is the first report showing a detrimental effect after zona manipulation without blastomere biopsy. There are over 400 papers on assisted hatching and zona thinning in the literature with the majority having reported clinical results. Generally speaking, two types of outcomes have been reported: (I) an improvement in pregnancy and/or implantation rate, or (II) no effect of the intervention. The paper by Valojerdi et al. adds a new category to this list: a discernible detrimental effect of the intervention. In general, it is not surprising that outcomes have been so varied following zona pellucida manipulation, particularly considering the many different approaches used and the varied circumstances under which the investigations have been conducted. It is a considerable task to sort through all the studies and clinical trials. The latest Cochrane Review of the assisted hatching literature was published earlier this year (Das et al., 2009Das S. Blake D. Farquhar C. Seif M.M.W. Assisted hatching on assisted conception (IVF and ICSI).Cochrane Database System. Rev. 2009; https://doi.org/10.1002/14651858.CD001894.pub4Crossref PubMed Scopus (63) Google Scholar). The abstract of this study does not detail the long list of its findings and conclusions and anyone interested enough in this technique should perhaps read the entire document (which is nearly 80 pages long). The conclusion of this review is that in certain embryos assisted hatching has some clinical benefit, including those that were thawed or devitrified. Assisted hatching in the largest acceptable cohort of papers increased the chance of pregnancy, but not that of miscarriage. Yet, in the paper by Valojerdi et al., zona thinning appears detrimental in devitrified embryos. The authors provide a concise analysis of what could have caused this outcome, noting that similar studies do not confirm their findings. The message from this important work is that circumstances under which clinical trials involving methodology are conducted may not be comparable. Operator skill and experience and an understanding of the complexities of tools such as lasers play a critical role and, if compromised, can undermine a perfectly acceptable randomization protocol in a clinical trial. In the case of lasers, responsible manufacturers of certified instruments have made a significant effort to make their instruments sensitive and apparently fullproof for the inexperienced user. However, following manufacturer’s instructions carefully may not be enough. For instance embryologists usually calibrate the laser using ink painted on one side of a regular glass slide, but the Petri dish is not made of glass and the embryo is much nearer to the lens in a dish than the ink on a slide. Thinning the zona pellucida over one quarter of the embryo’s circumference involves a relatively large amount of energy, which may penetrate beyond the zona and into the embryo proper. Calibration errors may result in extensive release of energy into the embryo since the laser will not be properly focused. This is just one possible explanation for the observations in the study of Valojerdi et al. Although assisted hatching was introduced into clinical practice some 20 years ago, the method has not yet been standardized. This is unfortunate since it contributes to variability in results. Relying on publications and manufacturer guidelines alone is not always sufficient for proper application of complex technologies. Therefore careful (small) pilot studies should be conducted prior to large-scale trials in order to avoid unintended and unexpected detrimental effects in large numbers of cases.

Streptococcal pyrogenic exotoxin B antibodies in a mouse model of glomerulonephritis

Streptococcal pyrogenic exotoxin B is an extracellular cysteine protease. Only nephritis-associated strains of group A streptococci secrete this protease and this may be involved in the pathogenesis of post-streptococcal glomerulonephritis. Mice were actively immunized with a recombinant protease inactive exotoxin B mutant or passively immunized with exotoxin B antibody. Characteristics of glomerulonephritis were measured using histology, immunoglobulin deposition, complement activation, cell infiltration, and proteinuria. None of the mice given bovine serum albumin or exotoxin A as controls showed any marked changes. Immunoglobulin deposition, complement activation, and leukocyte infiltration occurred only in the glomeruli of exotoxin B-hyperimmunized mice. One particular anti-exotoxin B monoclonal antibody, 10G, was cross-reactive with kidney endothelial cells and it caused kidney injury and proteinuria when infused into mice. This cross-reactivity may be involved in the pathogenesis of glomerulonephritis following group A streptococcal infection.

The use of Lab-Tek tissue culture Chamber/ Slides and Flaskette for processing cultured monolayers for electron microscopy

In situ embedding is a preferable means for the ultrastructural study of cultured cell monolayers. However, the major difficulty is the separation of the polymerized plastic resin from the supporting substrates. This abstract demonstrates a simple, fast procedure for using existing products for cell culture and in situ embedding of monolayers. Epoxy block surfaces up to 10 cm2 can be easily separated from an untreated glass slide and sectioned vertically or horizontally for EM studies.The Lab-Tek tissue culture Chamber/Slides or Flaskette are constructed so that 1 to 8 chamber compartments or a single flask is attached to a regular glass slide by gaskets. Different cell lines or procedures can be performed on the same chamber/slide. When the plastic chambers and gasket are removed, the glass slide can be coverslipped and filed for reference. We use these products routinely for cell cultures. When an EM study is needed, we fix the cell monolayers in situ within the chambers or flask, dehydrate with ethanol, infiltrate and embed in an epoxy resin.