Liposomal detection devices and methods of making and using such devices are disclosed. Such liposomal detection devices may be used to detect microbes by detecting a byproduct of microbial metabolism, or may be used to detect changes in pH and/or changes in temperature. Liposomal detection devices may include a first liposome encapsulating a first destabilizing compound and a second liposome encapsulating a second destabilizing compound. The first liposome may destabilize in response to the detection of the target compound or change to release the first destabilizing compound which may destabilize the second liposome. A matrix, such as a hydrogel matrix, may encase the first liposome and the second liposome.

Nanoparticles for use in assay methods for detecting analytes in samples, which comprise a signal inducing agent, e.g. a transition-metal catalyst or a chemiluminophore, a chemiluminophore precursor, a soluble absorber, or a soluble absorber precursor. After binding to an analyte, the nanoparticle is dissociated by a chemical or physical trigger, e.g. an organic solvent or ultrasound, to release the signal inducing agent, which releases a detectable signal via a physical or chemical reaction. The nanoparticles comprising a chemiluminophore, a chemiluminophore precursor, a soluble absorber, or a soluble absorber precursor can also effect chemical reactions that serve as signal amplifiers.

The invention provides a method for quantifying the number of target entities that were successfully encapsulated into a microfluidic compartment such as a microfluidic droplet. The invention is predicated upon a continuous quantifiable detectable signal corresponding to the quantity of entities encapsulated in a microfluidic compartment. The present invention is useful in the context of high throughput microfluidic screening approaches which require thorough signal normalization in order to reliably improve signal to noise ratio and to reliably identify screening hits.

The present disclosure relates to a novel method for lateral flow immunoassay (LFIA) by utilizing plasmonic enhancement strategy. More specifically, the present disclosure provides a plasmonic enhanced lateral flow sensor (pLFS) concept by introducing a liposome-based amplification of the colorimetric signals on the lateral flow platform for ultrasensitive detection of pathogens.

The present disclosure provides a system comprising a communication interface and computer for assigning a label to the biomolecule fingerprint, wherein the label corresponds to a biological state. The present disclosure also provides a sensor arrays for detecting biomolecules and methods of use. In some embodiments, the sensor arrays are capable of determining a disease state in a subject.

The present disclosure provides a system comprising a communication interface and computer for assigning a label to the biomolecule fingerprint, wherein the label corresponds to a biological state. The present disclosure also provides a sensor arrays for detecting biomolecules and methods of use. In some embodiments, the sensor arrays are capable of determining a disease state in a subject.

This invention is a functionalized diamond crystal with high dispersibility in high ionic strength solution and/or with specific targeting ability, which comprise a diamond crystal and a fatty acid layer. The fatty acid layer works a surfactant and provides a specific targeting feature for the diamond crystal. The feature of the surfactant makes the diamond crystal being easily dispersed in biological surrounding (e.g., phosphate saline buffer) and the feature of specific targeting ability provides the diamond crystal with specific recognizing specific targets. This invention allows researchers to use diamond crystal as a marker for specific labelling.

Methods are disclosed for performing a bioassay, comprising activating capsules containing a signal precursor that is hydrolysable from a latent form in which substantially no signal is generated to a form in which it is able to generate a detectable signal, said activating comprising treating said capsules with heat and with an acid or a base catalyzing solution, the combination of said heat and the pH of the catalyzing solution being such as to hydrolyze said precursor to the form in which it is able to generate a detectable signal.

Embodiments of the present disclosure provide a nanoparticle based platform, and nanoallergens for identifying, evaluating and studying allergen mimotopes as multiple copies of a single mimotope or various combinations on the same particle. The nanoparticle is extremely versatile and allows multivalent binding to IgEs specific to a variety of mimotopes, simulating allergen proteins. Nanoparticles can include various molecular ratios of components. For example, the nanoallergens can include about 0.1-40% mimotope-lipid conjugate and about 60-99.9% lipid. The mimotope-lipid conjugate includes a mimotope, a first linker, and lipid molecule. Nanoallergens can be used in in vitro and in vivo applications to identify a specific patient's sensitivity to a set of epitopes and predict a symptomatic clinical response, identify allergen epitopes through blind screening peptide sequences from allergen protein, and in a clinical application similar to a scratch test.

The present disclosure relates to a novel method for lateral flow immunoassay (LFIA) by utilizing plasmonic enhancement strategy. More specifically, the present disclosure provides a plasmonic enhanced lateral flow sensor (pLFS) concept by introducing a liposome-based amplification of the colorimetric signals on the lateral flow platform for ultrasensitive detection of pathogens.