| The two main problems currently stalling the efficient treatment of cancer has been detecting cancer early enough in the disease process for successful treatment, and treating cancer cells while avoiding excessive toxicity to normal tissues. Arguably the most important factor in the fight against cancer, besides prevention is early detection because the cancer will be easier to treat and less likely to have drug resistance.;The work highlighted in this thesis attempts to address the issues related to the effective treatment and management of cancer. The objective of this work is to develop new materials and methods for co-assembly of drugs and imaging agents that permit quantitative imaging of drug delivery and disease progression. By using molecular imaging technique to non-invasively study and detect various molecular markers of diseases can allow for much earlier diagnosis, earlier treatment, and better prognosis that will eventually lead to personalized medicine. Exploration of particulates and polymeric carriers is gaining momentum in diagnostic imaging, initiated by successful therapies using long circulating liposomes. However, liposomes are challenging pharmaceuticals, which include many chemical components, require complex drug encapsulation strategies, and must be physically sheared to control their particle diameter and polydispersity. Polymeric nanocarriers have emerged as an alternative to liposomes as carriers of drugs and imaging agents. Co-inclusion of therapeutic and imaging agents, into these carriers might be advantageous because they increase solubility of hydrophobic agents, may enhance permeability across physiological barriers, alter drug biodistribution, increase local bioavailability and reduce of side effects. |
