The present invention relates to compounds which bind and/or inhibit prostate-specific membrane antigen (PSMA) comprising at least one group electron dense substituent (EDS), and at least one moiety which is amenable to radiolabeling; and therapeutic and diagnostic uses thereof.

Provided herein are compositions, systems, and methods for minimally-invasive assessment of toxicity-induced tissue injury. In particular, external (e.g., whole-body) scanning is employed to detect toxicity-induced injuries, such as those caused by chemotherapeutics.

Compositions and methods for visualizing tissue under illumination with near-infrared radiation, including compounds comprising near-infrared, closed chain, sulfo-cyanine dyes and prostate specific membrane antigen ligands are disclosed.

The present invention relates to a compound of a pharmaceutically acceptable salt thereof of formula (I) wherein (A) is at least one motif specifically binding to cell membranes of neoplastic cells; (B) at least one chelator moiety of radiometals; (C) a dye moiety; x.sub.1 is a spacer or a chemical single bond covalently connecting (A) to the rest of the molecule; x.sub.2 is a spacer or a chemical single bond covalently connecting (C) to the rest of the molecule. The invention further relates to compositions comprising said compounds as well as a method for detecting neoplastic cells in a sample in vitro with the aid of the compounds or composition. ##STR00001##

The present disclosure provides peptide constructs for diagnostic imaging and therapeutic applications, using pegylated peptides which exhibit specific binding for a target molecule of interest, such as a biomarker of a disease or disorder.

This invention relates to novel thioflavin derivatives, methods of using the derivatives in, for example, in vivo imaging of patients having neuritic plaques, pharmaceutical compositions comprising the thioflavin derivatives and method of synthesizing the compounds. The compounds find particular use in the diagnosis and treatment of patients having diseases where accumulation of neuritic plaques are prevalent. The disease states or maladies include but are not limited to Alzheimer's Disease, familial Alzheimer's Disease, Down's Syndrome and homozygotes for the apolipoprotein E4 allele.

Disclosed are multivalent, integrin-receptor antagonists that are useful in a variety of therapeutic, prophylactic, and/or diagnostic imaging modalities. In illustrative embodiments, such compounds have been prepared and utilized in the imaging, detection, localization, and/or quantitation of one or more samples of biological interest. Similarly, these compounds, as well as formulations comprising them, find utility in the prevention, treatment, and/or amelioration of one or more symptoms of a disease, abnormal condition, dysfunction, etc., including, for example proliferative diseases such as cancer in affected animals. In certain embodiments, fluorescently- or radio-labeled-non-peptidic, multivalent integrin α.sub.vβ.sub.3 compounds are provided. Compositions including such compounds have been shown to have utility in detecting, localizing, quantitating, and/or imaging integrin α.sub.vβ.sub.3 receptor-expressing cells, including, for example, cancer cells in vitro, in vivo, and/or in situ.

Compositions and methods for evaluating a pharmacokinetic property of an ophthalmic agent administered by intravitreal injection are provided.

The invention relates to Cathepsin-binding compounds bound to a carrier comprising a diagnostic moiety, for use in the diagnosis of inflammatory diseases, and/or for use in the diagnosis of neoplastic diseases, wherein the Cathepsin-binding compound binds to inflammatory cells of the tumour stroma. The invention also relates to Cathepsin B-targeting compounds and Cathepsin B-binding and liposome-binding compounds.

The present invention relates to novel lipophilic macrocyclic ligands, the complexes thereof, in particular radioactive complexes, and the uses of same in medical imaging and/or in therapy, in particular in interventional radiology.