ß-Galactosidase-Activatable Fluorescent and Photoacoustic Imaging of Tumor Senescence.

ß-Galactosidase (ß-gal) is the gold standard marker of cellular senescence, which is linked with various age-related diseases. Therefore, it is essential to develop more excellent probes that can real-time monitor ß-gal activity in cellular senescence in vivo. Fluorescent/photoacoustic (FL/PA) dual-modal imaging possesses excellent sensitivity and spatial resolution. To our knowledge, there has been no tumor-targeted FL/PA probe to image cellular senescence by monitoring the activity of ß-gal in vivo. Therefore, we developed a tumor-targeted FL/PA probe (Gal-HCy-Biotin) for ß-gal-activatable imaging of tumor senescence. Gal-HCy without tumor-targeted biotin is used as a control probe. Gal-HCy-Biotin is superior to Gal-HCy due to the higher kinetic parameter of Gal-HCy-Biotin than Gal-HCy in vitro. Moreover, biotin could help Gal-HCy-Biotin enter and accumulate in tumor cells with higher FL/PA signal. In detail, Gal-HCy-Biotin or Gal-HCy could image senescent tumor cells with 4.6-fold or 3.5-fold FL enhancement and 4.1-fold or 3.3-fold PA enhancement. Gal-HCy-Biotin or Gal-HCy could image tumor senescence with 2.9-fold or 1.7-fold FL enhancement and 3.8-fold or 1.3-fold PA enhancement. We envision that Gal-HCy-Biotin will be applied for FL/PA imaging of tumor senescence in clinic.

Caspase-3-Responsive Fluorescent/Photoacoustic Imaging of Tumor Apoptosis.

Caspase-3 is an essential executor in apoptosis, and its activation has been regarded as a biomarker of cell apoptosis. The development of Caspase-3-responsive multimodal probes is a promising research prospect. Fluorescent/photoacoustic (FL/PA) imaging has attracted considerable attention due to the high sensitivity of FL as well as the high spatial resolution and penetration depth of PA. To our knowledge, there has been no tumor-targeted FL/PA probe to monitor the activity of Caspase-3 in vivo. Therefore, we developed a tumor-targeted FL/PA probe (Bio-DEVD-HCy) for Caspase-3-responsive imaging of tumor apoptosis. Ac-DEVD-HCy without tumor-targeted biotin is used as a control probe. In vitro experiments indicated that Bio-DEVD-HCy is superior to Ac-DEVD-HCy because of the higher kinetic parameter of Bio-DEVD-HCy in comparison to Ac-DEVD-HCy. Cell and tumor imaging results suggested that Bio-DEVD-HCy could enter and accumulate in tumor cells with higher FL/PA signal with the help of tumor-targeted biotin. In detail, Bio-DEVD-HCy or Ac-DEVD-HCy could image apoptotic tumor cells with 4.3-fold or 3.5-fold FL enhancement and 3.4-fold or 1.5-fold PA enhancement. Bio-DEVD-HCy or Ac-DEVD-HCy could image tumor apoptosis with 2.5-fold or 1.6-fold FL enhancement and 4.1-fold or 1.9-fold PA enhancement. We envision that Bio-DEVD-HCy will be applied for FL/PA imaging of tumor apoptosis in clinical settings.

Caspase-1-responsive fluorescence biosensors for monitoring endogenous inflammasome activation.

The activation of inflammasome leads to secretion of inflammatory factors and cell pyroptosis that are critical in the pathogenesis of various chronic and acute inflammatory diseases. Recruitment and activation of caspase-1 is a marker of inflammasome activation. However, there is still lack of real-time and efficient methods to detect the activation of inflammasome, especially in vivo. Herein, we developed two activatable caspase-1-responsive fluorescence biosensors, WEHD-HCy and YVAD-HCy, to specifically monitor the activation of inflammasome in vivo. Our in vitro study demonstrated that WEHD-HCy and YVAD-HCy can sensitively and specifically respond to caspase-1 activation. Moreover, these biosensors can efficiency and specifically activated in the common inflammatory disease model, including inflammatory bowel disease, Salmonella infection, and acute arthritis. In particular, WEHD-HCy is more advantageous than YVAD-HCy to specifically image of caspase-1 activity both in vitro and in vivo. These caspase-1-responsive fluorescence biosensors provide an efficient, rapid, and in situ tool for monitoring inflammasome activation, and have the potential to be suitable for clinical diagnosis of various inflammatory diseases associated with inflammasome activation.

Tumor-Targeted Fluorescent/Photoacoustic Imaging of Legumain Activity In Vivo.

Legumain has been identified as a target for diagnosis and treatment of associated cancers. Therefore, real-time imaging of legumain activity in vivo is helpful in diagnosing and evaluating therapeutic efficacy of associated cancers. Fluorescent/photoacoustic (FL/PA) dual-modal imaging developed rapidly because of its good sensitivity and spatial resolution. As far as we know, a tumor-targeted probe for FL/PA imaging of legumain activity in vivo has not been reported. Hence, we intended to develop a tumor-targeted hemicyanine (HCy) probe (HCy-AAN-Bio) for FL/PA imaging of legumain in vivo. The control probe HCy-AAN does not have tumor-targeting ability. Legumain can specifically cleave HCy-AAN-Bio or HCy-AAN with the generation of FL/PA signal while more HCy-AAN-Bio could be recognized by legumain than HCy-AAN with higher sensitivity in vitro. Due to the tumor-targeting ability, HCy-AAN-Bio could image 4T1 cells with an additional 1.3-fold FL enhancement and 1.9-fold PA enhancement than HCy-AAN. In addition, HCy-AAN-Bio could image legumain activity in vivo with an additional 1.5-fold FL enhancement and 1.9-fold PA enhancement than HCy-AAN. We expected that HCy-AAN-Bio will be a powerful tool for early diagnosis of associated cancer.

An esterase-activatable curcumin prodrug for tumor-targeting therapy.

A tumor-targeting therapy strategy is urgently needed to increase the accumulation of drugs in tumors and reduce the side effects in normal tissues. Herein, we developed an esterase-activatable curcumin prodrug Cur-RGD for tumor-targeting therapy. Armed with the tumor-targeting RGD peptide and in situ esterase-triggered drug release, this prodrug Cur-RGD can efficiently improve the therapeutic effect of curcumin in tumors.