A metabolic-dysfunction associated steatotic liver acinus biomimetic induces pancreatic islet dysfunction in a coupled microphysiology system.
Julio AlemanK RavikumarConnor WiegandMark E SchurdakLawrence A VernettiDillon GavlockCeleste ReeseRichard DeBiasioGreg LaRoccaYulder Daniel AngaritaAlbert GoughAlejandro Soto-GutierrezJaideep BehariVijay K YechoorMark T MiedelAndrew M SternIpsita BanerjeeD Lansing TaylorPublished in: bioRxiv : the preprint server for biology (2024)
Preclinical and clinical studies suggest that lipid-induced hepatic insulin resistance is a primary defect that predisposes to dysfunction in pancreatic islets, implicating a perturbed liver-pancreas axis underlying the comorbidity of T2DM and MASLD. To investigate this hypothesis, we developed a human biomimetic microphysiological system (MPS) coupling our vascularized liver acinus MPS (vLAMPS) with primary islets on a chip (PANIS) enabling MASLD progression and islet dysfunction to be quantitatively assessed. The modular design of this system (vLAMPS-PANIS) allows intra-organ and inter-organ dysregulation to be deconvoluted. When compared to normal fasting (NF) conditions, under early metabolic syndrome (EMS) conditions, the standalone vLAMPS exhibited characteristics of early stage MASLD, while no significant differences were observed in the standalone PANIS. In contrast, with EMS, the coupled vLAMPS-PANIS exhibited a perturbed islet-specific secretome and a significantly dysregulated glucose stimulated insulin secretion (GSIS) response implicating direct signaling from the dysregulated liver acinus to the islets. Correlations between several pairs of a vLAMPS-derived and a PANIS-derived secreted factors were significantly altered under EMS, as compared to NF conditions, mechanistically connecting MASLD and T2DM associated hepatic factors with islet-derived GLP-1 synthesis and regulation. Since vLAMPS-PANIS is compatible with patient-specific iPSCs, this platform represents an important step towards addressing patient heterogeneity, identifying complex disease mechanisms, and advancing precision medicine.
Keyphrases
- insulin resistance
- oxidative stress
- metabolic syndrome
- early stage
- signaling pathway
- endothelial cells
- high throughput
- type diabetes
- lps induced
- diabetic rats
- magnetic resonance
- blood glucose
- stem cells
- magnetic resonance imaging
- emergency medical
- squamous cell carcinoma
- case report
- skeletal muscle
- high fat diet
- immune response
- fatty acid
- mesenchymal stem cells
- uric acid
- radiation therapy
- lymph node
- room temperature
- glycemic control
- ionic liquid
- soft tissue