Microstructure-Driven Self-Transport and Convection of Water on Membrane Surface for Ultra-Fast, Highly Sensitive, Low-Cost Lateral-Flow Assays.

Lateral-flow assay (LFA) is one of the most commonly used detection technologies, in which the chromatographic membranes are currently used as the lateral-flow membrane (e.g., nitrocellulose membrane, NC Mem). However, several disadvantages of existing chromatographic membranes limit the performance of LFA, including relatively low flow velocity of sample solution and relatively more residuals of sample on membrane, which increase detection time and detection noise. Herein, a surface structure membrane (SS Mem) is proposed, which enables fast self-transport of water with a convection manner and realizes low residuals of sample on membrane surface after the flow. On SS Mem, the flow velocity of water is 7.1-fold higher, and the residuals of sample are decreased by 60-67%, comparing those in NC Mem. SS Mem is used as lateral-flow membrane to prepare lateral-flow strips of nanogold LFA and fluorescence LFA for rapid detection of SARS CoV-2 nucleocapsid protein. These LFAs require 210 s per detection, with limits of detection of 3.98 pg mL-1 and 53.3 fg mL-1, sensitivity of 96.5%, and specificity of 90%. The results suggest that SS Mem enables ultrafast, highly sensitive lateral-flow immunoassays and shows great potential as a new type of lateral-flow membrane to broaden the application of LFA.

Transplanted neural stem cells promote nerve regeneration in acute peripheral nerve traction injury: assessment using MRI.

OBJECTIVE: The purpose of our study was to monitor neural stem cells (NSCs) transplanted in acute peripheral nerve traction injury and to use MRI to assess the ability of NSCs to promote nerve regeneration. MATERIALS AND METHODS: After labeling with gadolinium-diethylene triamine pentaacetic acid (gadopentetate dimeglumine) and fluorescent dye (PKH26), 5 × 10(5) NSCs were grafted to acutely distracted sciatic nerves in 21 New Zealand White rabbits. In addition, 5 × 10(5) unlabeled NSCs (n = 21) and vehicle alone (n = 21) subjects were injected as a control. Serial MRI was performed with a 1.5-T scanner to determine the distribution of grafted cells. Sequential T1 and T2 values of the nerves and functional recovery were measured over a 70-day follow-up period, with histologic assessments performed at regular intervals. RESULTS: The distribution and migration of labeled NSCs could be tracked with MRI until 10 days after transplantation. Compared with vehicle control, nerves grafted with labeled or unlabeled NSCs had better functional recovery and showed improved nerve regeneration but exhibited a sustained increase of T1 and T2 values during the phase of regeneration. CONCLUSION: Gadopentetate dimeglumine-based labeling allowed short-term in vivo MRI tracking of NSCs grafted in injured nerves. NSCs transplantation could promote nerve regeneration in acute peripheral nerve traction injury as shown by a prolonged increase of nerve T1 and T2 values.