Simone Manini scite author profile

An important number of surgical procedures for creation of vascular access (VA) in haemodialysis patients still results in non-adequate increase in blood flow (non-maturation). The rise in blood flow in arteriovenous shunts depends on vascular remodelling. Computational tools to predict the outcome of VA surgery would be important in this clinical context. The aim of our investigation was then to develop a 0D/1D computational model of arm vasculature able to simulate vessel wall remodelling and related changes in blood flow. We assumed that blood vessel remodelling is driven by peak wall shear stress. The model was calibrated with previously reported values of radial artery diameter and blood flow after end-to-end distal fistula creation. Good agreement was obtained between predicted changes in VA flow and in arterial diameter after surgery and corresponding measured values. The use of this computational model may allow accurate vascular surgery planning and ameliorate VA surgery outcomes.

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The Vascular Modeling Toolkit: A Python Library for the Analysis of Tubular Structures in Medical Images

Izzo¹,

Steinman²,

Manini³

et al. 2018

JOSS

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Preliminary detection of lung hypoperfusion in discharged Covid-19 patients during recovery

Patelli

Paganoni

Besana

et al. 2020

European Journal of Radiology

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A Framework for Different Levels of Integration of Computational Models Into Web-Based Virtual Patients

Kononowicz¹,

Narracott²,

Manini³

et al. 2014

J Med Internet Res

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BackgroundVirtual patients are increasingly common tools used in health care education to foster learning of clinical reasoning skills. One potential way to expand their functionality is to augment virtual patients’ interactivity by enriching them with computational models of physiological and pathological processes.ObjectiveThe primary goal of this paper was to propose a conceptual framework for the integration of computational models within virtual patients, with particular focus on (1) characteristics to be addressed while preparing the integration, (2) the extent of the integration, (3) strategies to achieve integration, and (4) methods for evaluating the feasibility of integration. An additional goal was to pilot the first investigation of changing framework variables on altering perceptions of integration.MethodsThe framework was constructed using an iterative process informed by Soft System Methodology. The Virtual Physiological Human (VPH) initiative has been used as a source of new computational models. The technical challenges associated with development of virtual patients enhanced by computational models are discussed from the perspectives of a number of different stakeholders. Concrete design and evaluation steps are discussed in the context of an exemplar virtual patient employing the results of the VPH ARCH project, as well as improvements for future iterations.ResultsThe proposed framework consists of four main elements. The first element is a list of feasibility features characterizing the integration process from three perspectives: the computational modelling researcher, the health care educationalist, and the virtual patient system developer. The second element included three integration levels: basic, where a single set of simulation outcomes is generated for specific nodes in the activity graph; intermediate, involving pre-generation of simulation datasets over a range of input parameters; advanced, including dynamic solution of the model. The third element is the description of four integration strategies, and the last element consisted of evaluation profiles specifying the relevant feasibility features and acceptance thresholds for specific purposes. The group of experts who evaluated the virtual patient exemplar found higher integration more interesting, but at the same time they were more concerned with the validity of the result. The observed differences were not statistically significant.ConclusionsThis paper outlines a framework for the integration of computational models into virtual patients. The opportunities and challenges of model exploitation are discussed from a number of user perspectives, considering different levels of model integration. The long-term aim for future research is to isolate the most crucial factors in the framework and to determine their influence on the integration outcome.

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pyNS: An Open-Source Framework for 0D Haemodynamic Modelling

Manini¹,

Antiga²,

Botti

et al. 2014

Ann Biomed Eng

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A number of computational approaches have been proposed for the simulation of haemodynamics and vascular wall dynamics in complex vascular networks. Among them, 0D pulse wave propagation methods allow to efficiently model flow and pressure distributions and wall displacements throughout vascular networks at low computational costs. Although several techniques are documented in literature, the availability of open-source computational tools is still limited. We here present python Network Solver, a modular solver framework for 0D problems released under a BSD license as part of the archToolkit ( http://archtk.github.com ). As an application, we describe patient-specific models of the systemic circulation and detailed upper extremity for use in the prediction of maturation after surgical creation of vascular access for haemodialysis.

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Patient-Specific Model of Arterial Circulation for Surgical Planning of Vascular Access

et al. 2012

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Computational Model for Prediction of Fistula Outcome

Remuzzi

Manini²

2014

J Vasc Access

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Simone Manini

Validation of a patient-specific hemodynamic computational model for surgical planning of vascular access in hemodialysis patients

Computational model for simulation of vascular adaptation following vascular access surgery in haemodialysis patients

The Vascular Modeling Toolkit: A Python Library for the Analysis of Tubular Structures in Medical Images

Preliminary detection of lung hypoperfusion in discharged Covid-19 patients during recovery

A Framework for Different Levels of Integration of Computational Models Into Web-Based Virtual Patients

pyNS: An Open-Source Framework for 0D Haemodynamic Modelling

Patient-Specific Model of Arterial Circulation for Surgical Planning of Vascular Access

Computational Model for Prediction of Fistula Outcome

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