Bulk transcriptome analysis Observations Validations Highlights Liver organoids from patients with BA exhibited aberrant morphology and disturbed apical-basal organization. Transcriptomic analysis of BA organoids revealed a shift from cholangiocyte to hepatocyte transcriptional signatures. Beta-amyloid accumulation was observed around the bile ducts in BA livers. Exposure to beta-amyloid induced aberrant morphology in control organoids. Beta-amyloid accumulation represents a novel finding with pathobiological implications and diagnostic potential for BA.
Conductive
polymer hydrogels (CPHs) hold significant promise in
broad applications, such as bioelectronics and energy devices. Hitherto,
the development of a facile and scalable synthesis method for CPHs
with high electrical conductivity and biocompatibility has still been
a challenge. Herein, we demonstrate highly conductive PPy–PEDOT:PSS
hybrid hydrogels which are prepared by a simple solution-mixing method.
This fabrication method involves the mixing of a pyrrole monomer with
a PEDOT:PSS dispersion, followed by in situ chemical
oxidative polymerization to form polypyrrole (PPy). The electrostatic
interaction between negatively charged PSS and positively charged
conjugated PPy facilitates the formation of PPy–PEDOT:PSS hybrid
hydrogels. The conductivity of the PPy–PEDOT:PSS hybrid hydrogels
is 867 S m–1. The PPy–PEDOT:PSS hybrid hydrogels
show excellent biocompatibility. Moreover, the PPy–PEDOT:PSS
hybrid hydrogels have a hierarchical porous structure which facilitates
the 3D cell culture within the hydrogels. The PPy–PEDOT:PSS
hybrid hydrogels exhibit excellent in situ biomolecular
detection and real-time cell proliferation monitoring performance,
indicating their potential as highly sensitive electrochemical biosensors
for bioelectronics applications. Our strategy for the fabrication
of CPHs with the electrostatic interaction between the negatively
charged conductive polymer and positively charged conductive polymer
would provide new opportunities for the design of highly conductive
conjugated hydrogels for bioelectronics applications and energy devices.
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