The invention provides a novel class of clearable, tumor-targeting and human protein-based MRI nanoprobes and contrast agents and their compositions, and methods of preparation and use thereof.

Disclosed are peptides and peptidomimetics that in some embodiments include the amino acid sequence KRGARST or (SEQ ID NO: 1), AKRGARSTA or (SEQ ID NO: 2), or CKRGARSTC (SEQ ID NO: 3). Also disclosed are conjugates and compositions that onclude the peptides and/or peptidomimetics, methods for directing a moiety to tumor lymphatic vasculature, methods for imaging tumor lymphatic vasculature, methods for reducing or inhibiting tumor metastasis, methods for reducing the number of tumor lymphatic vessels, methods for treating cancer, methods for treating a disease or disorder associated with a gC1q/p32 receptor biological activity, methods for detecting the presence of a gC1q/p32 receptor, methods for detecting interactions between gC1q/p32 receptors and the presently disclosed conjugates and compositions, methods for delivering the presently disclosed conjugates and compositions to gC1q/p32 receptors, methods for assessing gC1q/p32 receptor levels in cells, methods for identifying subjects having diseases associated with gC1q/p32 receptor biological activities, and methods for screening for compounds that interact with gC1q/p32 receptors.

The present invention relates to a superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body for magnetic resonance imaging and magnetic thermotherapy. According to the present invention, a superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body which has target directionality and a high density of ultrafine gold nanoparticles uniformly coupled to the surface of protein nanoparticles can be fabricated with neither a separate surface stabilization process nor a separate target directionality conferring process. Hence, the superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body according to the present invention is superior to conventional gold nanoparticles in terms of biocompatibility and has excellent target directionality as well as being identified to have a temperature elevation potential in an alternating magnetic field and a functionality as a T2-MRI contrast medium thanks to the superparamagnetism property of the ultrafine gold nanoparticles. Therefore, the superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body according to the present invention can be utilized as a core technology in the fields of magnetic thermotherapy and magnetic resonance imaging contrast media.

A matrix metalloprotease (MMP) activatable conjugate is provided to inhibit glioblastoma (GBM) proliferation through glioma tumor cell and glioma stem cell differentiation. The conjugate is structurally characterized by having dichloroacetate (DCA), as a therapeutic drug, linked, via a MMP cleavable peptide, to a nanoparticle suitable for magnetic resonance imaging (MRI) such as a superparamagnetic iron oxide (SIPO) or an ultra superparamagnetic iron oxide (uSIPO).

Nanoparticles described as metal-encapsulated carbonaceous dots or M@C-dots are disclosed. Also disclosed are specific M@C-dots with gadolinium, so called Gd@C-dots. These nanoparticles are biologically inert and preclude the release of metal in biological environments. In addition, despite a dimension exceeding the commonly recognized threshold for renal clearance, the disclosed nanoparticles can be efficiently cleared via urine after systematic injection. Methods of making and using such nanoparticles are also disclosed.

The disclosure pertains to conformational epitopes in A-beta, antibodies thereto and methods of making and using immunogens and antibodies specific thereto.

We have developed a model system of HIV reservoirs in neural cells by generating chimeric phosphorothioate-modified oligodeoxynucleotides (sODN) that specifically interact with neural cell DNA or RNA, and that further comprise a sequence of the HIV genome. In particular, we have conjugated the chimera sODN to a delivery vehicle (e.g. a superparamagnetic iron oxide nanoparticle (SPIO)) and have demonstrated specific delivery to neural cells, in vitro and in vivo. These model systems can be used to screen for agents that specifically target latent viral infection. In particular, using the model system, we have developed suicide MRI contrast agents that can be used to reduce the number of neural cells which harbor the virus, also provided herein. Our model system is translatable to other latent viruses as well.

This disclosure relates to nanoparticles comprising a surface molecule that binds or blocks PD-L1. In certain embodiments, the disclosure relates to methods of using peptides or nanoparticles disclosed herein for the treatment of cancer. In certain embodiments, the disclosure relates to methods of using nanoparticles disclosed herein for therapeutic and diagnostic applications.

Disclosed are peptides and peptidomimetics that in some embodiments include the amino acid sequence KRGARST or (SEQ ID NO: 1), AKRGARSTA or (SEQ ID NO: 2), or CKRGARSTC (SEQ ID NO: 3). Also disclosed are conjugates and compositions that include the peptides and/or peptidomimetics, methods for directing a moiety to tumor lymphatic vasculature, methods for imaging tumor lymphatic vasculature, methods for reducing or inhibiting tumor metastasis, methods for reducing the number of tumor lymphatic vessels, methods for treating cancer, methods for treating a disease or disorder associated with a gC1q/p32 receptor biological activity, methods for detecting the presence of a gC1q/p32 receptor, methods for detecting interactions between gC1q/p32 receptors and the presently disclosed conjugates and compositions, methods for delivering the presently disclosed conjugates and compositions to gC1q/p32 receptors, methods for assessing gC1q/p32 receptor levels in cells, methods for identifying subjects having diseases associated with gC1q/p32 receptor biological activities, and methods for screening for compounds that interact with gC1q/p32 receptors.

Compounds containing TRPV6-binding peptides and their use in the detection and diagnosis of cancer are described. Also described are methods for detecting and staging cancer that use the compounds of the invention. Compounds containing TRPV6-binding peptides are useful for the delivery of diagnostic and therapeutic agents to cells or tumors that express TRPV6.