Abstract
This article shows how to couple multiphysics and artificial neural networks to design computer models of human organs that autonomously adapt their behaviour to environmental stimuli. The model simulates motility in the intestine and adjusts its contraction patterns to the physical properties of the luminal content. Multiphysics reproduces the solid mechanics of the intestinal membrane and the fluid mechanics of the luminal content; the artificial neural network replicates the activity of the enteric nervous system. Previous studies recommended training the network with reinforcement learning. Here, we show that reinforcement learning alone is not enough; the input–output structure of the network should also mimic the basic circuit of the enteric nervous system. Simulations are validated against in vivo measurements of high-amplitude propagating contractions in the human intestine. When the network has the same input–output structure of the nervous system, the model performs well even when faced with conditions outside its training range. The model is trained to optimize transport, but it also keeps stress in the membrane low, which is exactly what occurs in the real intestine. Moreover, the model responds to atypical variations of its functioning with ‘symptoms’ that reflect those arising in diseases. If the healthy intestine model is made artificially ill by adding digital inflammation, motility patterns are disrupted in a way consistent with inflammatory pathologies such as inflammatory bowel disease.
Highlights
In Mary Shelley’s novel, Dr Frankenstein brings his creature to life by, in line with the contemporary theory of galvanism, pumping electricity into the creature’s nervous system
The multiphysics model is based on discrete multiphysics (DMP) [16] and combines two-particle methods: smooth particle hydrodynamics (SPH) to model the fluid [17] and the lattice spring model (LSM) to model the elastic membrane [18]
This is the baseline against which the adaptive model will be compared; the Methods section provides details on how SPH and LSM are implemented in the model
Summary
In Mary Shelley’s novel, Dr Frankenstein brings his creature to life by, in line with the contemporary theory of galvanism, pumping electricity into the creature’s nervous system. Away from galvanism, today scientists pursue the objective of bringing (digital) the so-called virtual physiological human to life [1], a computer analogue of the human body where new treatments, bold medical hypotheses and even disrupting ideas can be tested in a safe environment. This is the ultimate goal of in silico medicine: integrating computer models of the mechanical, physical and biochemical functions of the living human body into the virtual physiological human. This ability, known as homeostasis, is regulated by the ANS that adjusts the response of the organism to the perception of the environment [2]
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