Abstract: The present invention generally relates to microfluidic droplets and, including forming gels within microfluidic droplets. In some aspects, a fluid containing agarose or other gel precursors is transported into a microfluidic droplet, and caused to harden within the droplet, e.g., to form a gel particle contained within the microfluidic droplet. Surprisingly, a discrete gel particle may be formed even if the fluid containing the agarose or other gel precursor, and the fluid contained within the microfluidic droplet, are substantially immiscible. Other aspects of the present invention are generally directed to techniques for making or using such gels within microfluidic droplets, kits containing such gels within microfluidic droplets, or the like.

Abstract: The invention provides high-sensitivity methods for detection and quantification of target analytes in liquid samples (e.g., biological or environmental samples). The methods can be multiplexed to allow simultaneous detection and quantification of multiple target analytes that are contained in the same sample. The invention also provides related compositions and kits.

Abstract: The present invention generally relates to microfluidics and, in some embodiments, to the determination of cells. In some aspects, primers able to introduce restriction sites into certain amplified nucleic acids are used. For example, the primers may introduce restriction sites into normal (wild-type) nucleic acids, but be unable to introduce restriction sites into mutant nucleic acids, e.g., due to a mismatch in the nucleic acid sequences caused by the mutant. After amplification, the nucleic acids may be exposed to a suitable restriction enzyme, which may cleave normal nucleic acids but not the mutant nucleic acids. In this way, mutant nucleic acids may be relatively quickly identified. In some embodiments, cells may be contained within microfluidic droplets and assayed to determine the mutant cells. In certain cases, for example, the nucleic acids may be amplified within droplets and attached to suitable tags, e.g., prior to breaking or merging the droplets and sequencing of the nucleic acids.

Abstract: The present invention generally relates to microfluidic droplets and, including forming gels within microfluidic droplets. In some aspects, a fluid containing agarose or other gel precursors is transported into a microfluidic droplet, and caused to harden within the droplet, e.g., to form a gel particle contained within the microfluidic droplet. Surprisingly, a discrete gel particle may be formed even if the fluid containing the agarose or other gel precursor, and the fluid contained within the microfluidic droplet, are substantially immiscible. Other aspects of the present invention are generally directed to techniques for making or using such gels within microfluidic droplets, kits containing such gels within microfluidic droplets, or the like.

Abstract: The present invention generally relates to systems and methods for determining RNA in blood or other fluids. In certain embodiments, blood or other fluids may be treated to isolate or separate RNA, for example, from DNA, cells, and other material. In some cases, the RNA may arise from bacteria or other pathogens or foreign organisms that may be found within the blood or other fluid. In some cases, RNA stabilizing reagents, such as ammonium sulfate, may be added to stabilize RNA, then cells within the blood may be lysed to release the RNA (and other materials) from the cells, thereby producing a lysate. The lysate may be treated, e.g., to separate nucleic acids from other components within the lysate, and in some cases, DNA may be degraded, e.g., using DNAses or other suitable enzymes, leaving behind the RNA. The RNA can then be studied, purified, analyzed, amplified, stored, or the like.