Novel PET Imaging Probe for Quantitative Detection of Senescence In Vivo.

Real-time detection of cellular senescence remains a clinical challenge. Here, we aimed to develop a positron emission tomography (PET) imaging probe targeting senescence-associated ß-galactosidase (SA-ß-Gal), the most widely used biomarker of cellular senescence, and investigate its performance for real-time in vivo quantitative detection of cellular senescence. A stable PET imaging agent [68Ga]Ga-BGal was obtained with a high labeling yield (90.0 ± 4.3%) and a radiochemical purity (>95%). [68Ga]Ga-BGal displayed high sensitivity and specificity for ß-Gal both in vitro and in vivo. The reaction and uptake of the probe correlated with the ß-Gal concentration and reaction time. In PET imaging, high ß-Gal-expressing CT26.CL25 tumors and doxorubicin-treated HeLa tumors showed high signals from [68Ga]Ga-BGal, while a low signal was observed in CT26.WT and untreated HeLa tumors. In summary, we showcased successful PET imaging of senescence in preclinical models using probe [68Ga]Ga-BGal. This finding holds the potential for translating senescence imaging into clinical applications.

Simultaneous elution of polycyclic aromatic hydrocarbons and heavy metals from contaminated soil by two amino acids derived from beta-cyclodextrins.

Two highly water-soluble amino acids, which derived from beta-CDs, i.e., glutamic acid-beta-cyclodextrin (GluCD) and ethylene-diamine-beta-cyclodextrin (EDCD), were synthesized and were examined for their effect on solubilization of anthracene (ANT), complexation of cadmium (Cd2+), and elution removal of ANT and Cd2+ in soil. The results showed that GluCD and EDCD were powerful complexant for ANT and Cd2+. In the presence of 10 g/L GluCD and EDCD, the solubilization of ANT increased by 47.04 and 23.85 times compared to the control, respectively. GluCD resulted in approximately 90% complexation of Cd2+ while 70% complexation was observed for EDCD. Simultaneously, GluCD and EDCD could greatly enhance the elution removal of ANT and Cd2+ from soil. GluCD resulted in the highest elution efficiency of ANT and Cd2+. With the addition of 10 g/L GluCD, 53.5% of ANT and 85.6% of Cd2+ were eluted, respectively. The ANT had a negligible effect on the Cd2+ removal due to different complexing sites of ANT and Cd2+, while Cd2+ enhanced the ANT removal under the addition of GluCD because Cd2+ neutralized the -COOH group of GluCD. Adversely, the removal of ANT was decreased with Cd2+ under the addition of EDCD, this was due to the fact that Cd2+ enhanced the polarity of EDCD molecule and inhibited the complexation between ANT and EDCD. The study suggested that GluCD could be preferred and be successfully applied to remediation of heavy metals or organic compounds in contaminated soil.