The effect of linker type and recognition peptide conjugation chemistry on tissue affinity and cytotoxicity of charged polyacrylamide.

To increase colonoscopy competence in ambiguous situations (e.g. the existence of flat polyps), an explicit in situ (at real time) diagnosis at the molecular level is required. We have previously shown that the affinity of fluorescent cationic polyacrylamide (Flu-CPAA) to malignant regions in the colon mucosa can be improved by conjugating the recognition peptide EPPT1 to the polymer backbone (to form Flu-CPAA-Pep). Using another recognition peptide, namely VRPMPLQ, we elucidated in the present study the effect of linker type and conjugating methods on Flu-CPAA-VRPMPLQ cytotoxicity and on its affinity to cell lines as well as human colorectal cancer (CRC) biopsies. In order to derive the relationship between the response variable and the experimental factors in a minimal set of experiments, a computerized statistical design of experiment (DoE) strategy was implemented. Data were collected in a six-factor factorial design to study the effect of experimental factors (independent variables) on the ability of the Flu-CPAA polymers to bind specifically to the colon cancer cell lines or the human biopsies (the response). It was found that the presence of VRPMPLQ on the Flu-CPAA improved the polymer's affinity to the human CRC biopsies and to the colon cancer cell lines representing stage B in the Duke severity staging system. The cytotoxicity of Flu-CPAA with high charge density was reduced after conjugated with VRPMPLQ. The replacement of Ahx linker by PEG linker of similar length did not affect the affinity to the human biopsies, nor did it affect cytotoxicity. However, elongating the PEG linker reduced the in vitro affinity to the colon cancer cell lines and to human CRC biopsies. Changing the conjugation method from condensation (amide bond formation) to the click conjugation method did not affect the affinity properties of the polymers. It did reduce, however, the polymer cytotoxicity. We suggest that Flu-CPAA-Pep, with the VRPMPLQ peptide as a recognition moiety, could serve for early diagnosis and screening of CRC patients during endoscopic procedures.

Multi-modal detection of colon malignancy by NIR-tagged recognition polymers and ultrasound contrast agents.

To increase colonoscopy capability to discriminate benign from malignant polyps, we suggest combining two imaging approaches based on targeted polymeric platforms. Water-soluble cationized polyacrylamide (CPAA) was tagged with the near infrared (NIR) dye IR-783-S-Ph-COOH to form Flu-CPAA. The recognition peptide VRPMPLQ (reported to bind specifically to CRC tissues) was then conjugated with the Flu-CPAA to form Flu-CPAA-Pep which was then incorporated into echogenic microbubbles (MBs) made of polylactic acid (PLA) that are highly responsive to ultrasound. The ultimate design includes intravenous administration combined with local ultrasound and intra-colon inspection at the NIR range. In this proof of principle study PLA MBs were prepared by the double emulsion technique and loaded with several types of Flu-CPAA-Pep polymers. After insonation the submicron PLA fragments (SPF)-containing Flu-CPAA-Pep were examined in vitro for their ability to attach to colon cancer cells and in vivo (DMH induced rat model) for their ability to attach to colon malignant tissues and compared to the specific attachment of the free Flu-CPAA-Pep. The generation of SPF-containing Flu-CPAA-Pep resulted in a tissue attachment similar to that of the free, unloaded Flu-CPAA-Pep. The addition of VRPMPLQ to the polymeric backbone of the Flu-CPAA reduced cytotoxicity and improved the specific binding.

The relative roles of charge and a recognition peptide in luminal targeting of colorectal cancer by fluorescent polyacrylamide.

Real time detection of biomarkers at the mucosal level is imperative for the prevention and efficient treatment of colorectal cancer. Cationized polyacrylamide (CPAA) with increasing charge densities was prepared by radical polymerization of acrylamide and different mol% ratios of N-acryloyl, N'-(tert-butyl-carbonyl) diaminoethane. The NIR fluorophore derivative of IR-783, IR-783-S-Ph-COOH, was attached to the CPAA to give CPAA-783. After selecting the optimal IR-783-S-Ph-COOH ratio that avoids quenching, the preferential binding of the polymer was tested in SW-620, SW-480, HT-29, and LS-174T cancer cells. The optimal polymeric product was tested in situ in gut sac preparations of the dimethylhydrazine induced rat model. To increase the detection capabilities of CPAA-783, the FITC-labeled peptide EPPT1, that targets the cell transmembrane underglycosylated MUC-1 (uMUC-1), was conjugated to the polymer to obtain CPAA-783-EPPT1. The dually labeled modified polymer was tested in HT-29 and LS-174T cells (over expressing uMUC-1), followed by an examination in an orthotopic mouse model. CPAA-783 preferentially bound to the cancer cells, depending on CRC staging. The best binding occurred when the fraction of the cationic monomer was 100 mol%, labeled with 0.75 mol% of IR-783-S-Ph-COOH. An increase in the recognition of the dually labeled polymeric product, CPAA-783-EPPT1, towards HT-29 and LS-174T cells occurred in the lowest EPPT1molar ratio (0.63 mol%) only, probably due to quenching phenomena and steric hindrance. Similar observation was obtained in the orthotopic mice. It is concluded that fluorescently tagged CPAA can be used for the detection of malignant tissues in colorectal cancer after luminal instillation. Dually targeted CPAA with EPPT1is feasible, but requires further optimization.