Heterogeneity and Delayed Activation As Hallmarks of Self-Organization and Criticality in Excitable Tissue

Overview

Journal Front Physiol

Date 2019 Jul 24

PMID 31333504

Citations 14

Authors

Andraz Stozer

Rene Markovic

Jurij Dolensek

Matjaz Perc

Marko Marhl

Marjan Slak Rupnik

Marko Gosak

Affiliations

Soon will be listed here.

Abstract

Self-organized critical dynamics is assumed to be an attractive mode of functioning for several real-life systems and entails an emergent activity in which the extent of observables follows a power-law distribution. The hallmarks of criticality have recently been observed in a plethora of biological systems, including beta cell populations within pancreatic islets of Langerhans. In the present study, we systematically explored the mechanisms that drive the critical and supercritical behavior in networks of coupled beta cells under different circumstances by means of experimental and computational approaches. Experimentally, we employed high-speed functional multicellular calcium imaging of fluorescently labeled acute mouse pancreas tissue slices to record calcium signals in a large number of beta cells simultaneously, and with a high spatiotemporal resolution. Our experimental results revealed that the cellular responses to stimulation with glucose are biphasic and glucose-dependent. Under physiological as well as under supraphysiological levels of stimulation, an initial activation phase was followed by a supercritical plateau phase with a high number of global intercellular calcium waves. However, the activation phase displayed fingerprints of critical behavior under lower stimulation levels, with a progressive recruitment of cells and a power-law distribution of calcium wave sizes. On the other hand, the activation phase provoked by pathophysiologically high glucose concentrations, differed considerably and was more rapid, less continuous, and supercritical. To gain a deeper insight into the experimentally observed complex dynamical patterns, we built up a phenomenological model of coupled excitable cells and explored empirically the model's necessities that ensured a good overlap between computational and experimental results. It turned out that such a good agreement between experimental and computational findings was attained when both heterogeneous and stimulus-dependent time lags, variability in excitability levels, as well as a heterogeneous cell-cell coupling were included into the model. Most importantly, since our phenomenological approach involved only a few parameters, it naturally lends itself not only for determining key mechanisms of self-organized criticality at the tissue level, but also points out various features for comprehensive and realistic modeling of different excitable systems in nature.

Citing Articles

The effect of forskolin and the role of Epac2A during activation, activity, and deactivation of beta cell networks.

Klemen M, Dolensek J, Krizancic Bombek L, Pohorec V, Gosak M, Rupnik M Front Endocrinol (Lausanne). 2023; 14:1225486.

PMID: 37701894 PMC: 10494243. DOI: 10.3389/fendo.2023.1225486.

A primer on modelling pancreatic islets: from models of coupled β-cells to multicellular islet models.

Felix-Martinez G, Godinez-Fernandez J Islets. 2023; 15(1):2231609.

PMID: 37415423 PMC: 10332213. DOI: 10.1080/19382014.2023.2231609.

Functional characteristics of hub and wave-initiator cells in β cell networks.

Sterk M, Dolensek J, Klemen M, Krizancic Bombek L, Leitgeb E, Kercmar J Biophys J. 2023; 122(5):784-801.

PMID: 36738106 PMC: 10027448. DOI: 10.1016/j.bpj.2023.01.039.

High-resolution analysis of the cytosolic Ca events in β cell collectives in situ.

Postic S, Sarikas S, Pfabe J, Pohorec V, Krizancic Bombek L, Sluga N Am J Physiol Endocrinol Metab. 2022; 324(1):E42-E55.

PMID: 36449570 PMC: 9829482. DOI: 10.1152/ajpendo.00165.2022.

Ca2+ Oscillations, Waves, and Networks in Islets From Human Donors With and Without Type 2 Diabetes.

Gosak M, Yan-Do R, Lin H, MacDonald P, Stozer A Diabetes. 2022; 71(12):2584-2596.

PMID: 36084321 PMC: 9750953. DOI: 10.2337/db22-0004.

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