The present invention is related to a targeted type shell for drug delivery system. The object of the present invention is to provide the targeted type shell for DDS, which comprises a carbosilane dendrimer containing a silole produced by which is formed by utilizing the reaction between thiol group and alkyl halide, and a targeted protein containing a labeled proteins such as green fluorescent protein with a target recognition site. The shell may incorporate compounds having a variety of molecular weight and biopolymers, and selectively deliver them into targeted cells.

The present invention provides a protein fusion construct comprising a far-red cyanobacteriochrome (CBCR) domain linked to a heterologous domain, wherein the far-red CBCR domain comprises a CBCR polypeptide and a tetrapyrrole chromophore. The invention also provides nucleic acids, expression cassettes, vectors, and host cells for expression of the far-red CBCR protein fusion constructs. Methods for detecting cellular components, methods for imaging biological structures, and method for modulating cellular processes using the protein fusion constructs are also provided.

The invention relates to integrin binding peptides, pharmaceutical compositions comprising the peptides and to uses thereof as therapeutic, diagnostic, imaging and targeting agents.

A method and system to prevent sore throat infections in humans includes the administration of an active ingredient to a site on the mucus membranes of the throat of a human that inhibits adherence and promotes desorption of S. pyogenes to soft tissue surfaces, such as the pharyngeal and oral mucosa of a human. A mucoadhesive strip having a surface topography that resists bioadhesion of undesired bacteria that are typically present in a human's mouth is preferably employed and that has one or more encapsulated agents selected from the group consisting of an antibiotic; lactic acid bacteria; S. pyogenes modified by a CRISPR-Cas system to reduce one or more virulence factors; and a breath mint solution.

Advancements in solid tumor (e.g., renal cell carcinoma) treatments and imaging are described. The advancements are based on nanoformulations that: (i) overcome deliverability issues associated with anti-cancer compounds; (ii) have increased targeted delivery to tumors, and hypoxic cores of tumors due to the presence of targeting ligands; (iii) have increased delivery to the hypoxic cores of tumors due to engineered shapes; (iv) provide synergistic treatment combinations; and/or (v) overcome cancer cell resistance to therapeutic treatments.

Protein indicators useful for calcium imaging, in particular, red genetically-encoded calcium indicators (GECIs) disclosed herein rival best-of-class green GECIs in terms of sensitivity for detecting neural activity, and can be monitored in vivo. The presently-disclosed subject matter further includes a method of monitoring cell activity comprising stimulating a cell comprising a red GECI polypeptide; and detecting fluorescence emitted by the cell.

Closed cavity adjustable sensor mount systems and methods are disclosed. The sensor mount systems include a sealed, closed cavity enclosing a sensor and forming a closed cavity sensor assembly. The closed cavity sensor assembly may be tilted and/or translated relative to a platform in order to adjust the orientation of the sensor to align it with an imaging optical axis. Following alignment, the closed cavity sensor assembly may be permanently or reversibly fixed in place. The closed cavity adjustable sensor mount systems may be part of medical imaging systems such as endoscopic imaging systems and/or open field imaging systems.

Modified viruses and methods for preparing the modified viruses are provided. Vaccines that contain the viruses are provided. The viruses can be used in methods of treatment of diseases, such as proliferative and inflammatory disorders, including cancer, and as anti-tumor and/or antiangiogenic agents. The viruses also can be used in diagnostic methods.

There is disclosed a composition in the form of a nanoparticle. The nanoparticle composition has a diameter from 5 to 500 nanometers. The nanoparticle composition has i) a central core portion including magnetic Fe.sub.3O.sub.4 nanoparticles adapted to act as a heat source when subjected to a magnetic field and a chemotherapeutic agent configured to treat cancer tissues, ii)a shell portion including a shell member encapsulating said core portion, and iii)antibodies configured to target cancer stem cells and adhered to surface of said shell member. The chemotherapeutic agent is a heat shock protein inhibitor and is releasable on activation of the heat source due to the magnetic field, and the shell member is made of silica or a silica based material. Surface of the nanoparticle is modified with the antibodies capable of binding with a cluster of differentiation molecules on the cell surface of the target cancer stem cells, whereby by way of combination of specificity of the nanoparticle composition due to the antibody, thermo-therapeutic effect of the Fe.sub.3O.sub.4 nanoparticles, and release of the heat shock protein inhibitor on site at the target cancer stem cells, inhibition of the target cancer stem cells is synergistically and additionally enhanced is increased.

Provided herein are devices and methods used to produce tattoo biosensors that are based on spatially controlled intracutaneous gene delivery of optical reporters driven by specific transcription factor pathways for a given cytokine or other analyte. The biosensors can be specific to a given analyte, or more generically represent the convergence of several cytokines into commonly shared intracellular transcription factor pathways. These biosensors can be delivered as an array in order to monitor multiple cytokines. Biosensor redeployment can enable chronic monitoring from months to years. The tattooed biosensor array of the present invention includes endogenous reporter cells, naturally tuned to each patient's own biology and can be used to reliably measure the state of a patient in real-time.