How Different Albumin-Binders Drive Probe Distribution of Fluorescent RGD Mimetics.

The biodistribution of medical imaging probes depends on the chemical nature of the probe and the preferred metabolization and excretion routes. Especially targeted probes, which have to reach a certain (sub)cellular destination, have to be guided to the tissue of interest. Therefore, small molecular probes need to exhibit a well-balanced polarity and lipophilicity to maintain an advantageous bioavailability. Labelled antibodies circulate for several days due to their size. To alter the biodistribution behavior of probes, different strategies have been pursued, including utilizing serum albumin as an inherent transport mechanism for small molecules. We describe here the modification of an existing fluorescent RGD mimetic probe targeted to integrin αvß3 with three different albumin binding moieties (ABMs): a diphenylcyclohexyl (DPCH) group, a p-iodophenyl butyric acid (IPBA) and a fatty acid (FA) group with the purpose to identify an optimal ABM for molecular imaging applications. All three modifications result in transient albumin binding and a preservation of the target binding capability. Spectrophotometric measurements applying variable amounts of bovine serum albumin (BSA) reveal considerable differences between the compounds concerning their absorption and emission characteristics and hence their BSA binding mode. In vivo the modified probes were investigated in a murine U87MG glioblastoma xenograft model over the course of 1 wk by fluorescence reflectance imaging (FRI) and fluorescence mediated tomography (FMT). While the unmodified probe was excreted rapidly, the albumin-binding probes were accumulating in tumor tissue for at least 5 days. Considerable differences between the three probes in biodistribution and excretion characteristics were proved, with the DPCH-modified probe showing the highest overall signal intensities, while the FA-modified probe exhibits a low but more specific fluorescent signal. In conclusion, the modification of small molecular RGD mimetics with ABMs can precisely fine-tune probe distribution and offers potential for future clinical applications.

Fluorescent non-peptidic RGD mimetics with high selectivity for αVß3 vs αIIbß3 integrin receptor: novel probes for in vivo optical imaging.

Integrins are heterodimeric transmembrane protein receptors consisting of different α and ß subunits. α(v)ß(3) integrins are overexpressed on many tumor cells and tumor-associated angiogenic vessels, whereas α(IIb)ß(3) is a receptor for, e.g., fibrinogen and mediates platelet aggregation. In this study, a near-infrared fluorescent imaging probe has been designed and synthesized by conjugating fluorescent dyes to a non-peptidic, pharmacophore-based ligand, based on a molecular modeling design approach. Affinity values were determined, and in vitro cell binding assays and preliminary in vivo xenograft studies in nude mice were performed to evaluate target binding. Competition assays revealed excellent binding and selectivity to α(v)ß(3) compared to that for α(IIb)ß(3). In vitro, the probe showed high target binding on α(v)ß(3)-positive M-21 cells and negligible binding to α(v)ß(3)-negative MCF-7 cells. In vivo, the tracer is able to image target expression in U-87 xenografts with a maximum signal-to-noise ratio (SNR) of 2.5:1 at 24 h after injection.

Optimizing the bioavailability of small molecular optical imaging probes by conjugation to an albumin affinity tag.

Small molecular imaging probes are often found to be rapidly cleared from the circulation. In order to improve signal to noise ratio (SNR) by high probe accumulation in the target tissue we intended to prolong the presence of the probes in the circulation by exploiting inherent transport mechanisms. Human serum albumin (HSA) is playing an increasingly important role as a drug carrier in clinical settings and drugs directly bound to albumin or attached to albumin binding moieties have been successfully developed for treatment approaches. To optimize the bioavailability of existing fluorescent probes, a hydrophobic affinity tag is installed, which enhances albumin binding. In a first experiment an endothelin-A receptor (ETAR) probe is modified by inserting a trivalent linker, attaching an albumin affinity tag and labeling the conjugate with the fluorescent dye Cy 5.5. The spectroscopic properties of the conjugate are examined by photometer- and fluorometer measurements in comparison to a probe without albumin binding tag. Albumin binding was proven by agarose gel electrophoresis. The affinity towards ETAR was confirmed in vitro by cell binding assays on human fibrosarcoma cells (HT-1080) and in vivo by murine xenograft imaging studies. In vitro, the modified probe retains high target binding in the absence and presence of albumin. Binding could be blocked by predosing with ETAR antagonist atrasentan, proving specificity. The in vivo examinations in comparison to the established probe showed a reduced renal elimination and a prolonged circulation of the tracer resulting in significantly higher signal intensity (SI) at the target and a higher signal-to-noise ratio (SNR) between 3h and 96 h after injection. In summary, we designed a small molecular, non-peptidic fluorescent probe which targets ETAR and reversibly binds to serum albumins. The reversible binding to albumin enhances the biological half-life of the probe substantially and enables near infrared optical imaging of subcutaneous tumors for several days. This approach of reversibly attaching probes to serum albumin may serve as a tool to optimize tracer distribution for more precise target characterization in molecular imaging experiments.