New neurotensin analogue radiolabeled by 99m-technetium as a potential agent for tumor identification.

It has been shown that more than 75% of ductal pancreatic adenocarcinomas overexpressed neurotensin (NT) receptors. Overexpression of NT receptors has been reported in various human tumor types. Hence, a non-invasive diagnosis and staging method could be very beneficial. In this work, we describe radiolabeling and evaluation of new neurotensin analogues to target neurotensin receptor-positive tumors such as pancreatic carcinoma. Radiolabeling was performed at 95°C for 10 min using 99m Tc in the presence of tricine/EDDA exchange labeling. Radiochemical yield analysis involved ITLC and HPLC methods. A binding assay test was carried out in nine different concentrations of labeled neurotensin analogues in HT-29 cells. Radiopeptide-specific binding and internalization were studied in NT receptors expressing HT-29 cells. Biodistribution studies were performed in tumor-free BALB/c mice and HT-29 xenografted tumor-bearing nude mice. The peptide was efficiently labeled by 99m Tc with high radiochemical yields (>98%). The radioconjugate was thoroughly stable in the solution and human serum even for 24 hr. The radiolabeled peptide showed high affinity (32.66 ± 4.01 nm) and specificity internalization (>%18 after 4 hr) to HT-29 cells. The radiopeptide efficiently showed tumor size and location in tumor-bearing nude mice. In biodistribution, a receptor-specific uptake of radiopeptide was observed in neurotensin receptor-positive organs such as intestine. Uptake in the tumor was 4.59 ± 0.23% ID/g after 2 hr. Owing to excellent stability, high affinity, rapid blood clearance, low accumulation in non-target organs, and high uptake in tumor, the 99m Tc-HYNIC-peptide is a potential agent for targeting of NTR-overexpressing tumor cells in clinical surroundings. When successfully executed in the clinical surrounding, non-invasive imaging of NTR-positive tumors with 99m Tc-labeled new neurotensin analogues could facilitate therapy procedure and monitoring.

Human Fibronectin Extra-Domain B (EDB)-Specific Aptide (APTEDB) Radiolabelling with Technetium-99m as a Potent Targeted Tumour-Imaging Agent.

BACKGROUND: Human fibronectin extra-domain B (EDB) is particularly expressed during angiogenesis progression. It is, thus, a promising marker of tumour growth. Aptides are a novel class of peptides with high-affinity binding to specific protein targets. APTEDB is an antagonist-like ligand that especially interacts with human fibronectin EDB. OBJECTIVE: This study was the first attempt in which the hydrazinonicotinamide (HYNIC)-conjugated APTEDB was labelled with technetium-99m (99mTc) as an appropriate radiotracer and tricine/EDDA exchange labeling. METHODS: Radiochemical purity, normal saline, and serum stability were evaluated by HPLC and radio-isotope TLC scanner. Other examinations, such as protein-binding calculation, dissociation radioligand binding assay, and partition coefficient constant determination, were also carried out. The cellular-specific binding of 99mTc- HYNIC-conjugated APTEDB was assessed in two EDB-positive (U87MG) and EDB-negative (U373MG) cell lines. Bio-distribution was investigated in normal mice as well as in U87MG and U373MG tumour-bearing mice. Eventually, the radiolabelled APTEDB was used for tumour imaging using planar SPECT. RESULTS: Radiolabelling was achieved with high purity (up to 97%) and accompanied by high solution (over 90% after overnight) and serum (80% after 2 hours) stability. The obtained cellular-specific binding ratio was greater than nine-fold. In-vivo experiments showed rapid blood clearance with mainly renal excretion and tumour uptake specificity (0.48±0.03% ID/g after 1h). The results of the imaging also confirmed considerable tumour uptake for EDB-positive cell line compared with the EDB-negative one. CONCLUSION: Aptides are considered to be a potent candidate for biopharmaceutical applications. They can be modified with imaging or therapeutic agents. This report shows the capability of 99mTc-HYNIC-APTEDB for human EDB-expressing tumours detection.