Experiments And Simulations of Thermometric Lateral Flow Immunoassay For Point-of-Care Testing

Temperature sensing is a promising method of enhancing the detection sensitivity of lateral flow immunoassay for point-of-care testing. A temperature increase of more than 100 °C can be readily achieved by photoexcitation of reporters like gold nanoparticles (GNPs) or colored latex beads (CLBs) on the strips with a laser power below 100 mW. Despite its promise, processes involved in the photothermal detection have not yet been well-characterized. Here, we provide a fundamental understanding of this thermometric assay by combining experiments and simulations using non-fluorescent CLBs as the reporters deposited on nitrocellulose membrane. By measuring the dependence of temperature rises on the number density of membrane-bound CLBs, we determined a 1.5-fold enhancement of the light absorption at 520 nm by the beads (diameter of 0.4 μm). The enhancement, however, was compromised by a 5-fold reduction of the incident laser power due to multiple scattering of the light in this highly porous medium. The limit of detection was measured to be 1 × 105 particles/mm2. In line with previous studies using GNPs as the reporters, the CLB-based thermometric assay provides a 10× higher sensitivity than color visualization, as demonstrated with the immunoassay for nucleocapsid proteins of the SARS-CoV-2 virus.

Making nanostructured materials from maize, milk and malacostraca

Nano-structured materials are used in electronics, diagnostics, therapeutics, smart packaging, energy management and textiles, areas critical for society and quality of life. However, their fabrication often places high demands on limited natural resources. Accordingly, renewable sources for the feedstocks used in their production are highly desirable. We demonstrate the use of readily available biopolymers derived from maize (zein), milk (casein) and malacostraca (crab-shell derived chitin) in conjunction with sacrificial templates, self-assembled monodisperse latex beads and anodized aluminium membranes, for producing robust surfaces coated with highly regular hyperporous networks or wire-like morphological features, respectively. The utility of this facile strategy for nano-structuring of biopolymers was demonstrated in a surface based-sensing application, where biotin-selective binding sites were generated in the zein-based nano-structured hyperporous network.

Therapeutic STING activation boosts microglia phagocytosis and ameliorates depression-like behaviors during chronic restraint stress

Background The STING-TBK1-IRF3 signaling pathway involves in modulating host innate immunity, however, the potential role of STING signaling pathway in chronic restraint stress model has not been determined. The aim of this study is to explore the underlying role of STING signaling pathway in regulating neuroinflammation, as well as to evaluate the therapeutic potential of STING agonist during chronic restraint stress. Methods C57BL/6 mice were subjected to 14-day intermittent restraint stress. Sucrose preference, elevated plus maze and tail suspension tests were measured in chronic restraint stress mice. Expression levels of proinflammatory cytokines were tested by QT-PCR and Luminex cytokine assays. The fluorescence-labeled latex beads, flow cytometry and CD68 positive cell counts were utilized to evaluate phagocytic abilities of microglia. Then, the ability of intracerebroventricular injection of STING agonist, 2’3-cGAMP, to reverse the depression-like behaviors and inflammatory cytokines was examined. Results We found that the expression levels of STING, p-TBK1, and p-IRF3 were remarkably decreased in chronic restraint stress mice, which was associated with decreased IFN-β secretion. Moreover, the STING agonist, 2’3-cGAMP, significantly alleviated the neuroinflammation and ameliorated depression-like behavior which depends on the functional STING activation. Furthermore, 2’3-cGAMP promoted microglia phagocytosis through STING-dependent IFN-β release, which was essential for recovery from neuroinflammation during chronic restraint stress. Conclusions These findings demonstrate that STING signaling pathway is a critical mediator in regulating microglia phagocytosis and may serve as a novel therapeutic target for chronic stress-related psychiatric diseases.

Ex vivo infection of human skin with herpes simplex virus 1 reveals mechanical wounds as insufficient entry portals via the skin surface

Herpes simplex virus 1 (HSV-1) enters its human host via the skin and mucosa. The open question is how the virus invades this highly protective tissue in vivo to approach its receptors in the epidermis and initiate infection. Here, we performed ex vivo infection studies in human skin to investigate how susceptible the epidermis and dermis are to HSV-1 and whether wounding facilitates viral invasion. Upon ex vivo infection of complete skin, only sample edges with integrity loss demonstrated infected cells. After removal of the dermis, HSV-1 efficiently invaded the basal layer of the epidermis, and from there, gained access to suprabasal layers. This finding supports a high susceptibility of all epidermal layers which correlated with the surface expression of the receptors nectin-1 and herpesvirus entry mediator (HVEM). In contrast, only single infected cells were detected in the separated dermis where minor expression of the receptors was found. Interestingly, after wounding, nearly no infection of the epidermis was observed via the skin surface. However, if the wounding of the skin samples led to breaks through the dermis, HSV-1 infected mainly keratinocytes via the damaged dermal layer. The application of latex beads revealed only occasional entry via the wounded dermis, however, facilitated penetration via the wounded skin surface. Thus, we suggest that although the wounded human skin surface allows particle penetration, the skin still provides barriers that prevent HSV-1 from reaching its receptors. Importance The human pathogen HSV-1 invades its host via the skin and mucosa which leads to primary infection of the epithelium. As the various epithelial barriers effectively protect the tissue against viral invasion, successful infection most likely depends on tissue damage. We addressed the initial invasion process in human skin by ex vivo infection to understand how HSV-1 overcomes physical skin barriers and reaches its receptors to enter skin cells. Our results demonstrate that intact skin samples allow viral access only from the edges, while the epidermis is highly susceptible once the basal epidermal layer serves as initial entry portal. Surprisingly, mechanical wounding did not facilitate HSV-1 entry via the skin surface although latex beads still penetrated via the lesions. Our results imply that successful invasion of HSV-1 depends on how well the virus can reach its receptors which was not accomplished by skin lesions under ex vivo conditions.

Therapeutic STING activation boosts microglia phagocytosis and ameliorates depression-like behaviors during chronic restraint stress

Background The STING-TBK1-IRF3 signaling pathway involves in modulating host innate immunity, however, the potential role of STING signaling pathway in chronic restraint stress model has not been determined. The aim of this study is to explore the underlying role of STING signaling pathway in regulating neuroinflammation, as well as to evaluate the therapeutic potential of STING agonist during chronic restraint stress. Methods C57BL/6 mice were subject to 14-day intermittent restraint stress. Sucrose preference, elevated plus maze and tail suspension tests were measured in chronic restraint stress mice. Expression levels of proinflammatory cytokines were tested by QT-PCR and Luminex cytokine assays. The fluorescence-labeled latex beads, flow cytometry and CD68 positive cell counts were utilized to evaluate phagocytic abilities of microglia. Then, the ability of intracerebroventricular injection of STING agonist, 2’3-cGAMP, to reverse the depression-like behaviors and inflammatory cytokines was examined. Results We found that the expression levels of STING, p-TBK1, and p-IRF3 were remarkably decreased in chronic restraint stress mice, which was associated with decreased IFN-β secretion. Moreover, the STING agonist, 2’3-cGAMP, significantly alleviated the neuroinflammation and ameliorated depression-like behavior which depends on the functional STING activation. Furthermore, 2’3-cGAMP promoted microglia phagocytosis through cGAMP-STING-dependent IFN-β release, which was essential for recovery from neuroinflammation during chronic restraint stress. Conclusions These findings demonstrate that STING signaling pathway is a critical mediator in regulating microglia phagocytosis and may serve as a novel therapeutic target for chronic stress-related psychiatric diseases.

Immunomodulation: Immunoglobulin Preparations Suppress Hyperinflammation in a COVID-19 Model via FcγRIIA and FcαRI

The rapid spread of SARS-CoV-2 has induced a global pandemic. Severe forms of COVID-19 are characterized by dysregulated immune response and “cytokine storm”. The role of IgG and IgM antibodies in COVID-19 pathology is reasonably well studied, whereas IgA is neglected. To improve clinical outcome of patients, immune modulatory drugs appear to be beneficial. Such drugs include intravenous immunoglobulin preparations, which were successfully tested in severe COVID-19 patients. Here we established a versatile in vitro model to study inflammatory as well as anti-inflammatory processes by therapeutic human immunoglobulins. We dissect the inflammatory activation on neutrophil-like HL60 cells, using an immune complex consisting of latex beads coated with spike protein of SARS-CoV-2 and opsonized with specific immunoglobulins from convalescent plasma. Our data clarifies the role of Fc-receptor-dependent phagocytosis via IgA-FcαRI and IgG-FcγR for COVID-19 disease followed by cytokine release. We show that COVID-19 associated inflammation could be reduced by addition of human immunoglobulin preparations (IVIG and trimodulin), while trimodulin elicits stronger immune modulation by more powerful ITAMi signaling. Besides IgG, the IgA component of trimodulin in particular, is of functional relevance for immune modulation in this assay setup, highlighting the need to study IgA mediated immune response.

Distinct Roles of Hemocytes at Different Stages of Infection by Dengue and Zika Viruses in Aedes aegypti Mosquitoes

Aedes aegypti mosquitoes are vectors for arboviruses of medical importance such as dengue (DENV) and Zika (ZIKV) viruses. Different innate immune pathways contribute to the control of arboviruses in the mosquito vector including RNA interference, Toll and Jak-STAT pathways. However, the role of cellular responses mediated by circulating macrophage-like cells known as hemocytes remains unclear. Here we show that hemocytes are recruited to the midgut of Ae. aegypti mosquitoes in response to DENV or ZIKV. Blockade of the phagocytic function of hemocytes using latex beads induced increased accumulation of hemocytes in the midgut and a reduction in virus infection levels in this organ. In contrast, inhibition of phagocytosis by hemocytes led to increased systemic dissemination and replication of DENV and ZIKV. Hence, our work reveals a dual role for hemocytes in Ae. aegypti mosquitoes, whereby phagocytosis is not required to control viral infection in the midgut but is essential to restrict systemic dissemination. Further understanding of the mechanism behind this duality could help the design of vector-based strategies to prevent transmission of arboviruses.

Understanding the interactions of poly(methyl methacrylate) and poly(vinyl chloride) nanoparticles with BHK-21 cell line

Microplastic and nanoplastic particles are prevalent in the environment and are beginning to enter the living system through multiple channels. Currently, little is known about the impact of plastic nanoparticles in living organisms. In order to investigate the health impact of micro- and nanoparticles of common polymers in a systematic way, luminescent plastic nanoparticles from two common polymers, polyvinyl chloride (PVC) and poly (methyl methacrylate) (PMMA) with relatively narrow size distribution are prepared using a nanoprecipitation method. As a model system, BHK-21 cells were exposed to polymer nanoparticles to understand the mode of uptake, internalization and biochemical changes inside the cells. The cellular effects of the nanoparticles were evaluated by monitoring the changes in cell viability, cell morphology, concentrations of reactive oxygen species (ROS), adenine triphosphate (ATP) and lactate dehydrogenase at different concentrations of the nanoparticles and time of exposure. PVC and PMMA nanoparticles induced a reduction in the cell viability along with a reduction of ATP and increase of ROS concentrations in a dose- and time-dependent manner. The plastic nanoparticles are internalized into the cell via endocytosis, as confirmed by Dynasore inhibition assay and colocalization with latex beads. Our findings suggest that plastic nanoparticle internalization could perturb cellular physiology and affect cell survival under laboratory conditions.

Substrate Stiffness Mediates Formation of Novel Cytoskeletal Structures in Fibroblasts during Cell–Microspheres Interaction

It is well known that living cells interact mechanically with their microenvironment. Many basic cell functions, like migration, proliferation, gene expression, and differentiation, are influenced by external forces exerted on the cell. That is why it is extremely important to study how mechanical properties of the culture substrate influence the cellular molecular regulatory pathways. Optical microscopy is one of the most common experimental method used to visualize and study cellular processes. Confocal microscopy allows to observe changes in the 3D organization of the cytoskeleton in response to a precise mechanical stimulus applied with, for example, a bead trapped with optical tweezers. Optical tweezers-based method (OT) is a microrheological technique which employs a focused laser beam and polystyrene or latex beads to study mechanical properties of biological systems. Latex beads, functionalized with a specific protein, can interact with proteins located on the surface of the cellular membrane. Such interaction can significantly affect the cell’s behavior. In this work, we demonstrate that beads alone, placed on the cell surface, significantly change the architecture of actin, microtubule, and intermediate filaments. We also show that the observed molecular response to such stimulus depends on the duration of the cell–bead interaction. Application of cytoskeletal drugs: cytochalasin D, jasplakinolide, and docetaxel, abrogates remodeling effects of the cytoskeleton. More important, when cells are plated on elastic substrates, which mimic the mechanical properties of physiological cellular environment, we observe formation of novel, “cup-like” structures formed by the microtubule cytoskeleton upon interaction with latex beads. These results provide new insights into the function of the microtubule cytoskeleton. Based on these results, we conclude that rigidity of the substrate significantly affects the cellular processes related to every component of the cytoskeleton, especially their architecture.