High-content imaging of human hepatic spheroids for researching the mechanism of duloxetine-induced hepatotoxicity.
Juan LiuRuihong LiTingting ZhangRui XueTingting LiZheng LiXiaomei ZhuangQi WangYu Ann ChenJiahong DongYouzhi ZhangYunfang WangPublished in: Cell death & disease (2022)
Duloxetine (DLX) has been approved for the successful treatment of psychiatric diseases, including major depressive disorder, diabetic neuropathy, fibromyalgia and generalized anxiety disorder. However, since the usage of DLX carries a manufacturer warning of hepatotoxicity given its implication in numerous cases of drug-induced liver injuries (DILI), it is not recommended for patients with chronic liver diseases. In our previous study, we developed an enhanced human-simulated hepatic spheroid (EHS) imaging model system for performing drug hepatotoxicity evaluation using the human hepatoma cell line HepaRG and the support of a pulverized liver biomatrix scaffold, which demonstrated much improved hepatic-specific functions. In the current study, we were able to use this robust model to demonstrate that the DLX-DILI is a human CYP450 specific, metabolism-dependent, oxidative stress triggered complex hepatic injury. High-content imaging analysis (HCA) of organoids exposed to DLX showed that the potential toxicophore, naphthyl ring in DLX initiated oxidative stress which ultimately led to mitochondrial dysfunction in the hepatic organoids, and vice versa. Furthermore, DLX-induced hepatic steatosis and cholestasis was also detected in the exposed EHSs. We also discovered that a novel compound S-071031B, which replaced DLX's naphthyl ring with benzodioxole, showed dramatically lower hepatotoxicities through reducing oxidative stress. Thus, we conclusively present the human-relevant EHS model as an ideal, highly competent system for evaluating DLX induced hepatotoxicity and exploring related mechanisms in vitro. Moreover, HCA use on functional hepatic organoids has promising application prospects for guiding compound structural modifications and optimization in order to improve drug development by reducing hepatotoxicity.
Keyphrases
- drug induced
- liver injury
- endothelial cells
- oxidative stress
- induced pluripotent stem cells
- diabetic rats
- major depressive disorder
- high glucose
- high resolution
- adverse drug
- pluripotent stem cells
- dna damage
- bipolar disorder
- emergency department
- type diabetes
- mental health
- signaling pathway
- heat shock
- mass spectrometry
- electronic health record
- heat shock protein
- climate change
- heat stress
- drug administration