All-Serotype Dengue Virus Detection through Multilayered Origami-Based Paper/Polymer Microfluidics.

The dengue virus (DENV) infection commonly triggers threatening seasonal outbreaks all around the globe (estimated yearly infections are in the order of 100 million, combining all the viral serotypes), testifying the need for early detection to facilitate disease management and patient recovery. The laboratory-based testing procedures for detecting DENV infection early enough are challenged by the need of resourced settings that result in inevitable cost penalty and unwarranted delay in obtaining the test results due to distance-related factors with respect to the patient's location. Recognizing that the introduction of alternative extreme point-of-care technologies for early detection may potentially mitigate this challenge largely, we develop here a multiplex paper/polymer-based detection strip that interfaces with an all-in-one simple portable device, synchronizing the pipeline of nucleic acid isolation, isothermal amplification, and colorimetric analytics as well as readout for detecting all the four serotypes of dengue viruses in around 30 min from about 50 μL of human blood serum with high specificity and sensitivity.

Fabricating Antipathogenic Interfaces via Nanoscale Topographies Inspired from Snake Skin.

Advancements in developing antipathogenic interfaces are critical in mitigating the risk of infection spread amid the practical limitations of hygienic control in crowded and resource-limited settings. Such requirements are also extremely compelling in busy patient care centers including intensive care units where the statutory maintenance of environmental standards often appears to be impractical because of the overflooded patient loads. While advances in surface engineering have emerged with great promises to cater these needs, the underlying technological complexities appear to be prohibitive against practicable applications amid constrained technological resources.