The present invention pertains to a ligand that contains a plurality of groups represented by formula (1) and is capable of multivalently binding to a glutamine transporter expressed in excess in a cancer cell compared to a normal cell.

Compounds (such as peptides or peptide mimetics) that bind to HIV RRE RNA are provided. In some examples, the compounds inhibit (for example, decrease) binding of Rev to the RRE RNA. In some embodiments, the compounds include two moieties, each of which bind to one of the Rev binding sites in the RRE. In some examples, the moieties include peptides or small molecules. In some examples, the peptides include an arginine-rich motif. The RRE binding compounds may be further linked to a detectable label or cargo moiety. Also provided are methods of treating or inhibiting HIV including administering one or more of the RRE binding compounds to a subject.

Compounds (such as peptides or peptide mimetics) that bind to HIV RRE RNA are provided. In some examples, the compounds inhibit (for example, decrease) binding of Rev to the RRE RNA. In some embodiments, the compounds include two moieties, each of which bind to one of the Rev binding sites in the RRE. In some examples, the moieties include peptides or small molecules. In some examples, the peptides include an arginine-rich motif. The RRE binding compounds may be further linked to a detectable label or cargo moiety. Also provided are methods of treating or inhibiting HIV including administering one or more of the RRE binding compounds to a subject.

Provided herein are protein contrast agents and targeted protein contrast agents, formulations thereof, and methods of use, including but not limited to, as a magnetic resonance imaging contrast agent.

Provided herein are porphyrinato-lanthanide complexes useful as theranostic agents and methods of preparation and use thereof. The porphyrinato-lanthanide complexes are useful in the treatment and imaging of cancer.

The present invention is based on the seminal discovery of a panel of targeting peptides and antibodies that can recognize AD brains at different stages of the disease, starting from early to advanced stage. The peptide probes described here are unique in the field and can be expected to advance understanding on early neurodegenerative changes associated with AD and improve the therapeutic outcomes by early detection and intervention in AD. Further, the invention provides antibodies that can be used to treat AD.

The present invention is based on the seminal discovery of a panel of targeting peptides and antibodies that can recognize AD brains at different stages of the disease, starting from early to advanced stage. The peptide probes described here are unique in the field and can be expected to advance understanding on early neurodegenerative changes associated with AD and improve the therapeutic outcomes by early detection and intervention in AD. Further, the invention provides antibodies that can be used to treat AD.

The present invention relates to GIP(1-30) analogues which selectively bind and activate the GIP receptor and comprise a chelating moiety capable of binding a metal ion and their use, for example in PET imaging or for radiotherapy.

A bone biospecific agent comprises a contrast material core, which is visible using Magnetic Resonance Imaging (MRI) or Computed Tomography (CT). The contrast material core is surrounded by a polymeric shell, which is functionalised with a bone-targeting peptide. In use, the peptide targets the biospecific agent to bone. The bone biospecific agent can be used in diagnostic imaging techniques, such as MRI and CT, and in imaging bone remodelling activities, detecting and treating pathological bone conditions and/or bone repair processes. The invention extends to the diagnosis and/or treatment of bone disease and bone pathologies using the biospecific agents.

A bone biospecific agent comprises a contrast material core, which is visible using Magnetic Resonance Imaging (MRI) or Computed Tomography (CT). The contrast material core is surrounded by a polymeric shell, which is functionalised with a bone-targeting peptide. In use, the peptide targets the biospecific agent to bone. The bone biospecific agent can be used in diagnostic imaging techniques, such as MRI and CT, and in imaging bone remodelling activities, detecting and treating pathological bone conditions and/or bone repair processes. The invention extends to the diagnosis and/or treatment of bone disease and bone pathologies using the biospecific agents.