Fanling Meng

Associate professor    Supervisor of Doctorate Candidates    Supervisor of Master's Candidates

  • Professional Title:Associate professor
  • Gender:Female
  • Status:Employed
  • Department:School of Life Science and Technology
  • Education Level:Postgraduate (Doctoral)
  • Degree:Doctoral Degree in Science
  • Alma Mater:美国纽约州立大学石溪分校

Paper Publications

Boosting the Photodynamic Degradation of Islet Amyloid Polypeptide Aggregates via a “Bait-Hook-Devastate” Strategy

Release time:2023-07-20Hits:

  • Journal:
    ACS Applied Materials & Interfaces
  • Included Journals:
    SCI
  • Volume:
    13
  • Issue:
    13
  • Page Number:
    14911–14919
  • ISSN No.:
    1944-8244
  • Key Words:
    amyloidogenic diseases amyloid aggregates photodynamic degradation polymer electrostatic interaction
  • DOI number:
    10.1021/acsami.1c00082
  • Date of Publication:
    2021-03-25
  • Impact Factor:
    9.229
  • Abstract:
    Photosensitizers that can generate reactive oxygen species (ROS) upon irradiation have emerged as promising agents for photodynamic degradation of toxic amyloid aggregates that are linked to many amyloidogenic diseases. However, due to the ultrastable β-sheet structure in amyloid aggregates and inefficient utilization of the generated ROS, it usually requires high stoichiometric concentration of the photosensitizer and/or intensive light irradiation to fully dissociate aggregates. In this work, we have developed a “bait-hook-devastate” strategy to boost the efficiency of the photodynamic degradation of amyloid aggregates. This strategy employs anionic polyacrylic acid as a bait to accumulate cationic human islet amyloid polypeptide (IAPP) aggregates and positively charged photosensitizer TPCI in a confined area through electronic interactions. Multiple characterization studies proved that the utilization rate of ROS generated by TPCI was remarkably improved via this strategy, which amplified the ability of TPCI to dissociate IAPP aggregates. Rapid and complete degradation of IAPP aggregates could be achieved by irradiating the system under very mild conditions for less than 30 min, and the IAPP-mediated cytotoxicity was also largely alleviated, providing a new paradigm to accelerate photodynamic degradation of amyloid aggregates for further practical applications.
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