A bimodal time-gated luminescence-magnetic resonance imaging nanoprobe based on a europium(III) complex anchored on BSA-coated MnO2 nanosheets for highly selective detection of H2O2.

A novel nanocomposite, [Eu(BTD)3(DPBT)]-BSA@MnO2, is reported to serve as an effective nanoprobe for bimodal time-gated luminescence (TGL) and magnetic resonance (MR) imaging of H2O2in vitro and in vivo. The nanoprobe was fabricated by immobilizing visible-light-excitable Eu3+ complexes in bovine serum albumin (BSA)-coated lamellar MnO2 nanosheets. The TGL of the Eu3+ complex was effectively quenched by the MnO2 nanosheets. Upon exposure to H2O2, the MnO2 nanosheets underwent reduction to Mn2+, which simultaneously triggered rapid, selective and sensitive "turn-on" responses toward H2O2 in both TGL and MR detection modes. The presence of a protective "corona" formed by BSA enables the nanoprobe to withstand high concentrations of glutathione (GSH), a strong reducing agent of MnO2 nanosheets. This capability allows the nanoprobe to be utilized for detecting H2O2 in living biosamples. The combined utilization of TGL and MR detection modes enables the nanoprobe to image H2O2 across a wide range of resolutions, from the subcellular level to the whole body, without any depth limitations. The results obtained from these modes can be cross-validated, enhancing the accuracy of the detection. The capability of the nanoprobe was validated by TGL imaging of endogenous and exogenous H2O2 in live HeLa cells, as well as bimodal TGL-MR imaging of H2O2 in tumor-bearing mice. The research achievements suggest that the integration of luminescent lanthanide complexes with protein-coated MnO2 nanosheets offers a promising bimodal TGL-MR sensing platform for H2O2in vitro and in vivo.

A tumor-targetable probe based on europium(III)/gadolinium(III) complex-conjugated transferrin for dual-modal time-gated luminescence and magnetic resonance imaging of cancerous cells in vitro and in vivo.

The synergy of magnetic resonance imaging (MRI) and time-gated luminescence imaging (TGLI) provides a robust platform with extensive spatial resolution (from submicrometer to hundred-micron) and unlimited penetration depth for visual detection of lesion tissues and target biomolecules. In this work, highly stable lanthanide (Eu3+ and Gd3+) complexes with a terpyridine polyacid ligand, CNSTTA-Ln3+, were chosen as signal reporters for TGLI (Ln3+ = Eu3+) and MRI (Ln3+ = Gd3+), respectively. After conjugating CNSTTA-Ln3+ with a tumor-targetable glycoprotein, transferrin (Tf), the obtained bioconjugate, showed low cytotoxicity and high stability and exhibited strong long-lived luminescence (Tf-CNSTTA-Eu3+, ϕ = 10.8%, τ = 1.27 ms), high magnetic resonance relaxivity (Tf-CNSTTA-Gd3+, r1 = 8.70 mM-1 s-1, r2 = 10.90 mM-1 s-1), and high binding affinity toward Tf receptor-overexpressed cancerous cells. On the basis of these features, a tumor-targetable probe was constructed by simply mixing Tf-CNSTTA-Eu3+ and Tf-CNSTTA-Gd3+, and successfully used for the bimodal TGLI and MRI of tumor cells in tumor-bearing mice. The bimodal imaging simultaneously provided the anatomical and molecular information of the tumor, which enabled the accuracy for tumor diagnosis to be mutually verified, and revealed the potential of Tf-CNSTTA-Gd3+/Eu3+ for the monitoring of cancer cells in vivo.

An activatable nanoprobe based on nanocomposites of visible-light-excitable europium(III) complex-anchored MnO2 nanosheets for bimodal time-gated luminescence and magnetic resonance imaging of tumor cells.

Bimodal imaging probes that combine magnetic resonance imaging (MRI) and photoluminescence imaging are quite appealing since they can supply both anatomical and molecular information to effectively ameliorate the accuracy of detection. In this study, an activatable nanoprobe, [Eu(BTD)3(DPBT)]@MnO2, for bimodal time-gated luminescence imaging (TGLI) and MRI has been constructed by anchoring visible-light-excitable Eu3+ complexes on lamellar MnO2 nanosheets. Due to the luminescence quenching effect and non-magnetic resonance (MR) activity of MnO2 nanosheets, the developed nanoprobe presents quite weak TGL and MR signals. After exposure to H2O2 or GSH, accompanied by the transformation from MnO2 to Mn2+, the nanoprobe exhibits rapid, sensitive, and selective "turn-on" responses towards GSH and H2O2 in TGL and MR detection modes. Furthermore, the nanoprobe displays high stability, low cytotoxicity, good biocompatibility and water dispersion. Given the high contents of GSH and H2O2 in cancer cells, the nanoprobe was used for the identification of cancer cells by TGLI of intracellular GSH and H2O2, as well as for the tracing of tumor cells in tumor-bearing mice by tumor-targeting in vivo MRI and TGLI of tumor tissues. The research outcomes proved the potential of [Eu(BTD)3(DPBT)]@MnO2 as a useful nanoprobe for the tracing and accurate detection of cancer cells in vitro and in vivo via bimodal TGLI and MRI.