👤 Kang Min Ok

Achieving long persistent luminescence (LPL) in fully organic materials with both hour-level duration and high thermal stability remains a fundamental challenge attributable to rapid exciton quenching and poor resistance to thermal disturbances. Herein, a trap engineering strategy is reported based on rigidified triphenylamine derivatives and boronic ester functionalization embedded in recycled poly(ethylene terephthalate) (PET), enabling the first fully organic polymer-based LPL system that exhibits simultaneously ultralong LPL and exceptional thermal robustness. Molecular conformation locking and optimized donor-acceptor charge transfer lead to deep trap states (≈1.03 eV), resulting in ambient LPL lifetimes exceeding 12 h. Remarkably, the luminescence is thermally enhanced by over 56 times at 500 K, rivaling high-performance inorganic phosphors. In addition, 980 nm near-infrared photo excitation further amplifies the emission, showcasing strong photo-stimulated luminescence capability. Taking advantage of PET's processability, 3D-printed luminescent structures are fabricated that retain LPL functionality and enable spatially resolved thermal sensing and real-time damage detection. This work not only introduces a sustainable and scalable platform for advanced thermal imaging and optoelectronics, but also sets a new benchmark in the design of heat-resistant organic LPL materials, bridging the gap between high-performance functionality and environmental compatibility. Show less

In this study, we used optical genome mapping (OGM), conventional karyotyping, and next-generation sequencing to analyze cytogenomic alterations in 91 cases of T-cell acute lymphoblastic leukemia/lymphoma (T-ALL). Whereas karyotyping detected abnormal karyotypes in 55% of cases, OGM identified cytogenetic abnormalities in 97.8% of the cases and provided clinically relevant information beyond karyotyping in ∼70% of cases. OGM detected gene rearrangements in 80% of cases, including 24 recurrent gene fusions and 21 previously unreported putative gene fusions in T-ALL. Copy number variants were detected in 93% of cases, with interstitial deletions the most common. Gene mutations were detected in 93% of cases, with NOTCH1 being most frequent (in 57% of cases). Combining all data, most T-ALL cases harbored 3 or more cytogenomic aberrations. Specific cytogenomic alterations differed among T-ALL subtypes as follows: rearrangements of BCL11B and PICALM::MLLT10, deletions of 7p, and mutations involving DNMT3A, WT1, TET2, IDH2, and FLT3 were common in early T-precursor and near-early T-precursor subtypes. Rearrangements of TLX1, KMT2A, STIL::TAL1, and NUP214::ABL1, deletions of 9p, and FBXW7 mutations were frequently associated with the cortical subtype. We conclude that integration of OGM and next-generation sequencing with karyotyping enables comprehensive cytogenomic profiling of T-ALL that improves detection of clinically relevant genomic alterations and may inform disease classification and future studies of risk stratification. Show less

Breast cancer remains a significant health concern, with triple-negative breast cancer (TNBC) being an aggressive subtype with poor prognosis. Epithelial-mesenchymal transition (EMT) is important in early-stage tumor to invasive malignancy progression. Snail, a central EMT component, is tightly regulated and may be subjected to proteasomal degradation. We report a novel proteasomal independent pathway involving chaperone-mediated autophagy (CMA) in Snail degradation, mediated via its cytosolic interaction with HSC70 and lysosomal targeting, which prevented its accumulation in luminal-type breast cancer cells. Conversely, Snail predominantly localized to the nucleus, thus evading CMA-mediated degradation in TNBC cells. Starvation-induced CMA activation downregulated Snail in TNBC cells by promoting cytoplasmic translocation. Evasion of CMA-mediated Snail degradation induced EMT, and enhanced metastatic potential of luminal-type breast cancer cells. Our findings elucidate a previously unrecognized role of CMA in Snail regulation, highlight its significance in breast cancer, and provide a potential therapeutic target for clinical interventions. Show less