Electroceutical fabric lowers zeta potential and eradicates coronavirus infectivity upon contact.

Coronavirus with intact infectivity attached to PPE surfaces pose significant threat to the spread of COVID-19. We tested the hypothesis that an electroceutical fabric, generating weak potential difference of 0.5 V, disrupts the infectivity of coronavirus upon contact by destabilizing the electrokinetic properties of the virion. Porcine respiratory coronavirus AR310 particles (105) were placed in direct contact with the fabric for 1 or 5 min. Following one minute of contact, zeta potential of the porcine coronavirus was significantly lowered indicating destabilization of its electrokinetic properties. Size-distribution plot showed appearance of aggregation of the virus. Testing of the cytopathic effects of the virus showed eradication of infectivity as quantitatively assessed by PI-calcein and MTT cell viability tests. This work provides the rationale to consider the studied electroceutical fabric, or other materials with comparable property, as material of choice for the development of PPE in the fight against COVID-19.

Flow-through electroporation based on constant voltage for large-volume transfection of cells.

Genetic modification of cells is a critical step involved in many cell therapy and gene therapy protocols. In these applications, cell samples of large volume (10(8)-10(9)cells) are often processed for transfection. This poses new challenges for current transfection methods and practices. Here we present a novel flow-through electroporation method for delivery of genes into cells at high flow rates (up to approximately 20 mL/min) based on disposable microfluidic chips, a syringe pump, and a low-cost direct current (DC) power supply that provides a constant voltage. By eliminating pulse generators used in conventional electroporation, we dramatically lowered the cost of the apparatus and improved the stability and consistency of the electroporation field for long-time operation. We tested the delivery of pEFGP-C1 plasmids encoding enhanced green fluorescent protein into Chinese hamster ovary (CHO-K1) cells in the devices of various dimensions and geometries. Cells were mixed with plasmids and then flowed through a fluidic channel continuously while a constant voltage was established across the device. Together with the applied voltage, the geometry and dimensions of the fluidic channel determined the electrical parameters of the electroporation. With the optimal design, approximately 75% of the viable CHO cells were transfected after the procedure. We also generalize the guidelines for scaling up these flow-through electroporation devices. We envision that this technique will serve as a generic and low-cost tool for a variety of clinical applications requiring large volume of transfected cells.

Efficient and stable gene expression into human osteoclasts using an HIV-1-based lentiviral vector.

Since osteoclasts are terminally differentiated cells without proliferating activity, efficient and stable gene expression into these cells remains a difficulty. In the current study, we investigate gene transduction into human preosteoclasts by a replication defective lentivirus-based vector containing a modified HIV-1 genome. Human preosteoclasts (differentiating osteoclasts) were transduced with lentiviruses bearing an enhanced green fluorescent protein (EFGP) reporter gene. Transduction efficiencies were measured by flow cytometry for EGFP protein expression. Sorted human transduced preosteoclasts were replated and differentiated under human macrophage colony-stimulating factor and human receptor activator of NF-kappaB ligand. Mature osteoclasts were then analyzed by the cell viability assay, TRACP assay, and pit formation assay. Efficient gene transduction was obtained at multiplicity of infection of 10, and gene expression lasted for over 4 weeks using our protocol. Lentiviral transduction did not affect osteoclast survival, formation, or function. These results establish an efficient method for gene transduction into human preosteoclasts using a lentiviral vector. Importantly, these transduced preosteoclasts could differentiate into mature osteoclasts without a negative impact from the lentiviruses. This protocol provides a new tool for studies of osteoclast biology. Further work in this area may open new avenues for the study of osteoclast gene signaling and gene therapy of disorders of osteoclast function.