Single Extracellular Vesicle Analysis Using Droplet Microfluidics.

Extracellular vesicles (EVs) are lipid-bound nanometer-sized vesicles released by all cell types that contain molecular payload such as proteins and/or nucleic acids. EVs are a key facet of cell-to-cell communication and have the potential to be used in the diagnosis of numerous diseases, chief among them being cancer. However, most methods of EV analysis struggle to identify the rare, malformed proteins indicative of tumor cells as tumor EVs represent only a tiny fraction of the bulk EVs present in the bloodstream. Here, we present a method of single EV analysis, utilizing droplet microfluidics to encapsulate EVs, which are labeled with DNA barcodes linked to antibodies, in droplets with the DNA extension used to amplify the signals associated with each EV. The amplified DNA can then be sequenced to assess the protein content of individual EVs, enabling the detection of rare proteins and EV subpopulations within a bulk EV sample.

Highly parallel, wash-free, and ultrasensitive centrifugal droplet digital protein detection in sub-microliter blood.

The ability to efficiently detect low-abundance protein biomarkers in tiny blood samples is a significant challenge in clinical and laboratory settings. Currently, high-sensitivity approaches require specialized instrumentation, involve multiple washing steps, and lack the ability to parallelize, preventing their widespread implementation. Herein, we developed a parallelized, wash-free, and ultrasensitive centrifugal droplet digital protein detection (CDPro) technology that achieves a femtomolar limit of detection (LoD) of target proteins with sub-microliters of plasma. The CDPro combines two techniques, namely a centrifugal microdroplet generation device and a digital immuno-PCR assay. Miniaturized centrifugal devices enable emulsification of hundreds of samples within 3 minutes using a common centrifuge. The bead-free digital immuno-PCR assay not only eliminates the need for multistep washing, but also possesses ultra-high detection sensitivity and accuracy. We characterized the performance of CDPro using recombinant interleukins (IL-3 and IL-6) as example targets and reported a LoD of 0.0128 pg mL-1. We also quantified IL-6 from 7 human clinical blood samples using the CDPro with only 0.5 µL plasma, which showed excellent agreement with an existing clinical protein diagnostic system with 25 µL plasma from those samples (R2 = 0.98).

A Customizable and Low-Cost Ultraviolet Exposure System for Photolithography.

For microfluidic device fabrication in the research, industry, and commercial areas, the curing and transfer of patterns on photoresist relies on ultraviolet (UV) light. Often, this step is performed by commercial mask aligner or UV lamp exposure systems; however, these machines are often expensive, large, and inaccessible. To find an alternative solution, we present an inexpensive, customizable, and lightweight UV exposure system that is user-friendly and readily available for a homemade cleanroom. We fabricated a portable UV exposure system that costs under $200. The wafer holder's adjustable height enabled for the selection of the appropriate curing distance, demonstrating our system's ability to be easily tailored for different applications. The high light uniformity across a 4" diameter wafer holder (light intensity error ~2.9%) was achieved by adding a light diffusing film to the apparatus. These values are comparable to the light uniformity across a 5" diameter wafer holder from a commercial mask aligner (ABM 3000HR Mask Aligner), that has a light intensity error of ~4.0%. We demonstrated the ability to perform photolithography with high quality by fabricating microfluidic devices and generating uniform microdroplets. We achieved comparable quality to the wafer patterns, microfluidic devices, and droplets made from the ABM 3000HR Mask Aligner.