The present invention provides a diagnostic reagent or assay for assessing the activity of a protease in vivo or in vitro and methods of detecting the presence of a cancerous or precancerous cell. The assays are comprised of two particles linked via an oligopeptide linkage that comprises a consensus sequence specific for the target protease. Cleavage of the sequence by the target protease can be detected visually or using various sensors, and the diagnostic results can be correlated with cancer prognosis.

A series of multicoordinating and multifunctional ligands optimized for the surface-functionalization of luminescent quantum dots (QDs) and gold nanoparticles (AuNPs) alike is disclosed. An L-aspartic acid precursor is modified with functionality, through simple peptide coupling chemistry, one or two lipoic acid (LA) groups and poly(ethylene glycol) (PEG) moieties in the same ligand. These ligands were combined with a new photoligation strategy to yield hydrophilic and reactive QDs that are colloidally stable over a broad range of conditions, including storage at nanomolar concentration and under ambient conditions.

A novel near-IR emitting cationic silver chalcogenide quantum dot with a mixed coating wherein the coating comprises of at least 2 different types of materials and is capable of luminescence at the desired near IR bandwidth at wavelengths of 800-850 nm. The quantum dot is fabricated via an advantageous single-step, homogeneous, aqueous method at a low temperature resulting a near IR emitting semiconductor quantum dot with high Quantum Yield, high transfection with low toxicity. The quantum dots may be used in medical imaging, tumor detection, drug delivery and labeling as well as in quantum dot sensitized solar cells.

A composition including a temperature sensitive biocompatible solder and at least one type of nanoparticles, characterized in that a first type of nanoparticles is a fluorescent nanothermometer, wherein the fluorescent nanothermometer exhibits an excitation maximum and temperature dependent emission spectrum each in the range of between 650 and 1350 nm. The composition can be used for laser tissue soldering.

The present disclosure provides methods of analyzing and/or purifying inorganic nanoparticles that may be functionalized with one or more dye group. Analyzing and/or purifying the inorganic nanoparticles includes utilizing liquid chromatography, such as, for example, high performance liquid chromatography (HPLC). Methods of the present disclosure may be used to determine the location of one or more dye groups on and/or in the inorganic nanoparticles. The present disclosure also provides methods of making inorganic nanoparticles and compositions of inorganic nanoparticles.

Living cells, such as red blood cells (RBCs) modified with functional micromotors with the aid of ultrasound propulsion and magnetic guidance. Iron oxide nanoparticles are loaded into the RBCs, where their asymmetric distribution within the cells results in a net magnetization, thus enabling magnetic alignment and guidance under acoustic propulsion. The RBC motors display efficient guided and prolonged propulsion in various biological fluids, including undiluted whole blood.

This disclosure relates to particles (e.g., nanoparticles and microparticles) that display multiple functionalized surface domains in a controlled mosaic pattern. The disclosure also provides simple methods to create various particles that have multiple functionalized surface domains while allowing the use of a wide variety of diverse core structures. The multiple functionalized domains provide controllable particle binding and orientation, and controlled and sustained drug release profiles.

In this work we have targeted two aspects of GQDs, Size and ROS to reduce their cytotoxicity. Small size can damage cell organelles and production of ROS (reactive oxygen species) can hamper cell machinery in multiple ways. We have shown that cytotoxicity can be significantly reduced by embedding GQDs inside the PEG matrix rather than creating a thin shell around each GQD. Thin PEG shell around GQD can control ROS production but cannot circumvent the toxicity due to small size. Thus it was essential to solve both the issues. We have used a simple electrochemical method (12 h at room temperature) for synthesizing GQDs and embedded them in PEG matrix via a simple one step hydrothermal reaction (24 h at 160 C.) involving only GQDs, PEG, and deionized water. The P-GQDs formed after hydrothermal reaction show nanoparticles of diameter of 80-100 nm containing GQDs entrapped in PEG matrix. MTT assay showed significant 60% cells viability at a very high concentration of 5.5 mg/mL of P-GQDs compared to 10-15% viability for C-GQD and H-GQD. ROS production by P-GQDs was least compared to C-GQD and H-GQD in cell free and intracellular ROS assay suggesting involvement of ROS in cytotoxicity. In this work we have solved the issue of cytotoxicity due to small size and ROS generation without compromising with fluorescence properties of GQDs. P-GQDs was used for bioimaging and drug delivery in HeLa cells. In short we can obtain biocompatible P-GQDs in very short span of time with minimal use of hazardous chemicals and simple methodology.

An engineered particle for detecting analytes in an environment includes an electromagnetic receiver that is configured to preferentially receive electromagnetic radiation of a specified polarization relative to the orientation of the electromagnetic receiver. The engineered particle additionally includes an energy emitter coupled to the electromagnetic receiver such that a portion of electromagnetic energy received by the electromagnetic receiver is transferred to and emitted by the energy emitter. The engineered particles are functionalized to selectively interact with an analyte. The engineered particle can additionally be configured to align with a directed energy field in the environment. The selective reception of electromagnetic radiation of a specified polarization and/or alignment with a directed energy field can enable orientation tracking of individual engineered particles, imaging in high-noise environments, or other applications. A method for detecting properties of the analyte of interest by interacting with the engineered particle is also provided.

Microvesicles play essential roles in disease progression. The present invention provides a novel microvesicle membrane protein and application thereof. Disclosed is method comprises phosphorylated CSE1L (cellular apoptosis susceptibility protein)- or CSE1L-binging agents for microvesicle isolation, analysis, or binding for disease diagnosis.