Multiple sclerosis (MS) is an inflammatory demyelinating disease of the CNS. Activated microglia/macrophages play a key role in the immunopathogenesis of MS and its corresponding animal models, experimental autoimmune encephalomyelitis (EAE). Microglia activation begins at early stages of the disease and is associated with elevated expression of the 18 kDa mitochondrial translocator protein (TSPO). Thus, positron emission tomography (PET) imaging of microglial activation using TSPO-specific radioligands could be valuable for monitoring disease-associated neuroinflammatory processes. EAE was induced in rats using a fragment of myelin basic protein, yielding acute clinical disease that reflects extensive spinal cord inflammation. Enhanced TSPO expression in spinal cords of EAE rats versus those of controls was confirmed by Western blot and immunohistochemistry. Biodistribution studies in control and EAE rats were performed using the TSPO radioligand
Protein tyrosine kinases (PTKs) play a pivotal role in signal transduction pathways and in the development and maintenance of various cancers. They are involved in multiple processes such as transcription, cell cycle progression, proliferation, angiogenesis and inhibition of apoptosis. Among the PTKs, the EGFR is one of the most widely studied and has emerged as a promising key target for the treatment of cancer. Indeed, several drugs directed at this receptor are FDA-approved and many others are at various stages of development. However, thus far, the therapeutic outcome of EGFR-targeted therapy is suboptimal and needs to be refined. Quantitative PET molecular imaging coupled with selective labelled biomarkers may facilitate in vivo EGFR-targeted drug efficacy by noninvasively assessing the expression of EGFR in tumor, guiding dose and regime by measuring target drug binding and receptor occupancy as well as potentially detecting the existence of a primary or secondary mutation leading to either drug interaction or failure of EGFR recognition by the drug. This review describes the attempts to develop labelled EGFR molecular imaging agents that are based either on low molecular weight tyrosine kinase inhibitors or monoclonal antibodies directed to the extracellular binding domain of the receptor to be used in nuclear medicine modalities.
Summary
Phage display has identified the dodecapeptide YHWYGYTPQNVI (GE11) as a ligand that binds to the EGFR but does not activate the receptor. Here we compare the EGFR binding affinities of GE11, EGF and their polyethyleneimine-polyethyleneglycol (PEI-PEG) conjugates. We find that although GE11 by itself does not exhibit measurable affinity to the EGFR, tethering it to PEI-PEG increases its affinity markedly, and complex formation with PolyIC further enhances the affinity to the sub-micromolar range. PolyIC/PPGE11 has a similar strong antitumor effect against EGFR over-expressing tumors in vitro and in vivo, as PolyIC/Polyethyleneimine-polyetheleneglycol-EGF (PolyIC/PP-EGF). Absence of EGFR activation, as previously shown by us (see text) and easier production of GE11 and GE11 conjugates, confer PolyIC/PPGE11 a significant advantage over similar EGF-based polyplexes as a potential therapy of EGFR over-expressing tumors.
Previous studies with the anilinoquinazoline epidermal growth factor receptor (EGFR) irreversible inhibitor [(11)C]-ML03 demonstrated a rapid metabolism of the tracer, which led to its low in vivo accumulation in EGFR overexpressing tumors. To enhance tumor uptake, the chemical structure of the compound was modified, and four new groups of EGFR inhibitors with a wide range of chemical reactivities were synthesized. Chemical reactivity assay of the compounds, performed with reduced glutathione (GSH), revealed that the group C (4-(dimethylamino)-but-2-enoic amide) derivative was the least chemically reactive against the nucleophilic attack of GSH. Nonetheless, it demonstrated a high inhibitory potency and bound irreversibly to the EGFR. Consequently, the blood stability of the group C compound (5a, ML04) labeled with (11)C was studied. In a time frame of 60 min, no radioactive metabolites were detected in blood. The stability of [(11)C]-5a, as indicated both from in vitro blood-stability assays and injection into nude rats, was significantly higher as compared to [(11)C]-ML03. Since group C presented a greater promise for tumor accumulation, it represents, to date, the most suitable candidate for radiolabeling with long-lived positron emission tomography (PET) radioisotopes.
One of the main limitations of the highly used cancer imaging technique, PET-CT, is its inability to distinguish between cancerous lesions and post treatment inflammatory conditions. The reason for this lack of specificity is that [(18)F]FDG-PET is based on increased glucose metabolic activity, which characterizes both cancerous tissues and inflammatory cells. To overcome this limitation, we developed a nanoparticle-based approach, utilizing glucose-functionalized gold nanoparticles (GF-GNPs) as a metabolically targeted CT contrast agent. Our approach demonstrates specific tumor targeting and has successfully distinguished between cancer and inflammatory processes in a combined tumor-inflammation mouse model, due to dissimilarities in angiogenesis occurring under different pathologic conditions. This study provides a set of capabilities in cancer detection, staging and follow-up, and can be applicable to a wide range of cancers that exhibit high metabolic activity.
Overexpression of the epidermal growth factor receptor tyrosine kinase (EGFR-TK) has been documented in numerous human cancers of epithelial origin, and was found to correlate with resistance to treatment and poor prognosis. Recognizing the central role that this receptor plays in cancer development and progression, various approaches have been developed to target it in order to more specifically eradicate cancer cells. These methods include, among others, low-molecular weight inhibitors of the TK domain that are commonly designed to treat those tumors that overexpress the EGFR. Nevertheless, no currently available assay provides non-invasive, longitudinal and sensitive quantitation of receptor levels in tumors so as to better identify candidate patients for EGFR-targeted therapies. Hence, attempts have been made to develop radiolabeled molecular imaging agents as potential bioprobes to quantitatively monitor treatment efficiency. Such EGFR-targeted bioprobes could not only improve patient selection and treatment monitoring, but also allow a direct delivery of radionuclides for radiotherapy. In this review, the role that EGFR plays in cancer development and therapy is briefly presented, followed by a short review of prominent milestones in the development of EGFR-TK inhibitors. These inhibitors constitute the fundamental core structure for the development of radiolabeled probes to visualize the EGFR in vivo. The considerations that need to be taken into account for the development of such probes will be presented, along with a critical examination on the progress that has been made thus far in the field.
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