IET Systems Biology
Volume 9, Issue 6, December 2015
Volumes & issues:
Volume 9, Issue 6
December 2015
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- Author(s): Heather J. Ruskin and Irina A. Roznovat
- Source: IET Systems Biology, Volume 9, Issue 6, page: 217 –217
- DOI: 10.1049/iet-syb.2015.0078
- Type: Article
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- Author(s): Emmanuel Sapin ; Ed Keedwell ; Tim Frayling
- Source: IET Systems Biology, Volume 9, Issue 6, p. 218 –225
- DOI: 10.1049/iet-syb.2015.0017
- Type: Article
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In this study, ant colony optimisation (ACO) algorithm is used to derive near-optimal interactions between a number of single nucleotide polymorphisms (SNPs). This approach is used to discover small numbers of SNPs that are combined into a decision tree or contingency table model. The ACO algorithm is shown to be very robust as it is proven to be able to find results that are discriminatory from a statistical perspective with logical interactions, decision tree and contingency table models for various numbers of SNPs considered in the interaction. A large number of the SNPs discovered here have been already identified in large genome-wide association studies to be related to type II diabetes in the literature, lending additional confidence to the results.
- Author(s): Stephen L. Smith ; Michael A. Lones ; Matthew Bedder ; Jane E. Alty ; Jeremy Cosgrove ; Richard J. Maguire ; Mary Elizabeth Pownall ; Diana Ivanoiu ; Camille Lyle ; Amy Cording ; Christopher J.H. Elliott
- Source: IET Systems Biology, Volume 9, Issue 6, p. 226 –233
- DOI: 10.1049/iet-syb.2015.0030
- Type: Article
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This study describes how the application of evolutionary algorithms (EAs) can be used to study motor function in humans with Parkinson's disease (PD) and in animal models of PD. Human data is obtained using commercially available sensors via a range of non-invasive procedures that follow conventional clinical practice. EAs can then be used to classify human data for a range of uses, including diagnosis and disease monitoring. New results are presented that demonstrate how EAs can also be used to classify fruit flies with and without genetic mutations that cause Parkinson's by using measurements of the proboscis extension reflex. The case is made for a computational approach that can be applied across human and animal studies of PD and lays the way for evaluation of existing and new drug therapies in a truly objective way.
- Author(s): Mohammad Majid al-Rifaie ; Ahmed Aber ; Duraiswamy Jude Hemanth
- Source: IET Systems Biology, Volume 9, Issue 6, p. 234 –244
- DOI: 10.1049/iet-syb.2015.0036
- Type: Article
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This study proposes an umbrella deployment of swarm intelligence algorithm, such as stochastic diffusion search for medical imaging applications. After summarising the results of some previous works which shows how the algorithm assists in the identification of metastasis in bone scans and microcalcifications on mammographs, for the first time, the use of the algorithm in assessing the CT images of the aorta is demonstrated along with its performance in detecting the nasogastric tube in chest X-ray. The swarm intelligence algorithm presented in this study is adapted to address these particular tasks and its functionality is investigated by running the swarms on sample CT images and X-rays whose status have been determined by senior radiologists. In addition, a hybrid swarm intelligence-learning vector quantisation (LVQ) approach is proposed in the context of magnetic resonance (MR) brain image segmentation. The particle swarm optimisation is used to train the LVQ which eliminates the iteration-dependent nature of LVQ. The proposed methodology is used to detect the tumour regions in the abnormal MR brain images.
- Author(s): Maell Cullen and KongFatt Wong-Lin
- Source: IET Systems Biology, Volume 9, Issue 6, p. 245 –258
- DOI: 10.1049/iet-syb.2015.0018
- Type: Article
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Dopamine (DA) is an important neurotransmitter for multiple brain functions, and dysfunctions of the dopaminergic system are implicated in neurological and neuropsychiatric disorders. Although the dopaminergic system has been studied at multiple levels, an integrated and efficient computational model that bridges from molecular to neuronal circuit level is still lacking. In this study, the authors aim to develop a realistic yet efficient computational model of a dopaminergic pre-synaptic terminal. They first systematically perturb the variables/substrates of an established computational model of DA synthesis, release and uptake, and based on their relative dynamical timescales and steady-state changes, approximate and reduce the model into two versions: one for simulating hourly timescale, and another for millisecond timescale. They show that the original and reduced models exhibit rather similar steady and perturbed states, whereas the reduced models are more computationally efficient and illuminate the underlying key mechanisms. They then incorporate the reduced fast model into a spiking neuronal model that can realistically simulate the spiking behaviour of dopaminergic neurons. In addition, they successfully include autoreceptor-mediated inhibitory current explicitly in the neuronal model. This integrated computational model provides the first step toward an efficient computational platform for realistic multiscale simulation of dopaminergic systems in in silico neuropharmacology.
- Author(s): Irina A. Roznovăţ and Heather J. Ruskin
- Source: IET Systems Biology, Volume 9, Issue 6, p. 259 –267
- DOI: 10.1049/iet-syb.2015.0048
- Type: Article
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Epigenetics is emerging as a fundamentally important area of biological and medical research that has implications for our understanding of human diseases including cancer, autoimmune and neuropsychiatric disorders. In the context of recent efforts on personalised medicine, a novel research direction is concerned with identification of intra-individual epigenetic variation linked to disease predisposition and development, i.e. epigenome-wide association studies. A computational model has been developed to describe the dynamics and structure of human intestinal crypts and to perform a comparative analysis on aberrant DNA methylation level induced in these during cancer initiation. The crypt framework, AgentCrypt, is an agent-based model of crypt dynamics, which handles intra- and inter-dependencies. In addition, the AgentCrypt model is used to investigate the effect of a set of potential inhibitors with respect to methylation modification in intestinal tissue during initiation of disease. Methylation level decrease over a relatively short period of 90 days is marked for the colon compared to the small intestine, although similar alterations are induced in both tissues. In addition, inhibitor effect is notable for abnormal crypt groups, with largest average methylation differences observed ≈0.75% lower in the colon and ≈0.79% lower in the small intestine with inhibitor present.
- Author(s): Tao You and Hong Yue
- Source: IET Systems Biology, Volume 9, Issue 6, p. 268 –276
- DOI: 10.1049/iet-syb.2015.0037
- Type: Article
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At early drug discovery, purified protein-based assays are often used to characterise compound potency. In the context of dose response, it is often perceived that a time-independent inhibitor is reversible and a time-dependent inhibitor is irreversible. The legitimacy of this argument is investigated using a simple kinetics model, where it is revealed by model-based analytical analysis and numerical studies that dose response of an irreversible inhibitor may appear time-independent under certain parametric conditions. Hence, the observation of time-independence cannot be used as sole evidence for identification of inhibitor reversibility. It has also been discussed how the synthesis and degradation of a target receptor affect drug inhibition in an in vitro cell-based assay setting. These processes may also influence dose response of an irreversible inhibitor in such a way that it appears time-independent under certain conditions. Furthermore, model-based steady-state analysis reveals the complexity nature of the drug–receptor process.
- Author(s): Alex Mace and Wenjia Wang
- Source: IET Systems Biology, Volume 9, Issue 6, p. 277 –284
- DOI: 10.1049/iet-syb.2015.0022
- Type: Article
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Plant cortical microtubules can form ordered arrays through interactions among themselves. When an incident microtubule collides with a barrier microtubule it may entrain if below a certain angle. Else it undergoes collision induced catastrophe (CIC) or crosses over the barrier microtubule. It has been proposed that katanin is necessary to create order by severing these crossover sites. The authors present a three-state computational model using Arabidopsis thaliana data to show how spontaneous catastrophe, the probability of CIC versus crossover, and katanin-mediated severing at the crossover sites affect microtubule ordering. The results of the systematic simulations show that (1), the microtubule order is more sensitive to the catastrophe rate than the rescue rate; (2), at 21°C, peak order is observed at 0.3 CIC and order decreases as CIC increases; and (3) at 0.2 CIC, katanin severing acting uniformly at all crossover sites is able to create order within a biologically reasonable time frame, but at lower CICs this becomes unrealistically fast. This would imply that at lower CIC levels preferential crossover site targeting and severing activity regulators would be required for katanin to bring about order.
- Author(s): Choujun Zhan ; Benjamin Yee Shing Li ; Lam Fat Yeung
- Source: IET Systems Biology, Volume 9, Issue 6, p. 285 –293
- DOI: 10.1049/iet-syb.2015.0014
- Type: Article
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In the field of systems biology, biological reaction networks are usually modelled by ordinary differential equations. A sub-class, the S-systems representation, is a widely used form of modelling. Existing S-systems identification techniques assume that the system itself is always structurally identifiable. However, due to practical limitations, biological reaction networks are often only partially measured. In addition, the captured data only covers a limited trajectory, therefore data can only be considered as a local snapshot of the system responses with respect to the complete set of state trajectories over the entire state space. Hence the estimated model can only reflect partial system dynamics and may not be unique. To improve the identification quality, the structural and practical identifiablility of S-system are studied. The S-system is shown to be identifiable under a set of assumptions. Then, an application on yeast fermentation pathway was conducted. Two case studies were chosen; where the first case is based on a larger state trajectories and the second case is based on a smaller one. By expanding the dataset which span a relatively larger state space, the uncertainty of the estimated system can be reduced. The results indicated that initial concentration is related to the practical identifiablity.
- Author(s): Arinze Akutekwe ; Huseyin Seker ; Shengxiang Yang
- Source: IET Systems Biology, Volume 9, Issue 6, p. 294 –302
- DOI: 10.1049/iet-syb.2015.0031
- Type: Article
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Accurate and reliable modelling of protein–protein interaction networks for complex diseases such as colorectal cancer can help better understand mechanism of diseases and potentially discover new drugs. Different machine learning methods such as empirical mode decomposition combined with least square support vector machine, and discrete Fourier transform have been widely utilised as a classifier and for automatic discovery of biomarkers for the diagnosis of the disease. The existing methods are, however, less efficient as they tend to ignore interaction with the classifier. In this study, the authors propose a two-stage optimisation approach to effectively select biomarkers and discover interactions among them. At the first stage, particle swarm optimisation (PSO) and differential evolution (DE) are used to optimise parameters of support vector machine recursive feature elimination algorithm, and dynamic Bayesian network is then used to predict temporal relationship between biomarkers across two time points. Results show that 18 and 25 biomarkers selected by PSO and DE-based approach, respectively, yields the same accuracy of 97.3% and F1-score of 97.7 and 97.6%, respectively. The stratified analysis reveals that Alpha-2-HS-glycoprotein was a dominant hub gene with multiple interactions to other genes including Fibrinogen alpha chain, which is also a potential biomarker for colorectal cancer.
- Author(s): Juyoung Park and Kyungtae Kang
- Source: IET Systems Biology, Volume 9, Issue 6, p. 303 –308
- DOI: 10.1049/iet-syb.2015.0011
- Type: Article
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Long-term electrocardiogram data can be acquired by linking a Holter monitor to a mobile phone. However, most systems of this variety are simply designed to detect arrhythmia through heartbeat classification, and do not provide any additional support for clinical decisions. HeartSearcher identifies patients with similar arrhythmias from heartbeat classifications, by summarising each patient's typical heartbeat pattern in the form of a regular expression, and then ranking patients according to the similarities of their patterns. Results obtained using electrocardiogram data from the MIT-BIH arrhythmia database show that this abstraction reduces the volume of heartbeat classifications by 98% on average, offering great potential to support clinical decisions.
- Author(s): Ayush Bansal ; Sunil Kumar ; Anurag Bajpai ; Vijay N. Tiwari ; Mithun Nayak ; Shankar Venkatesan ; Rangavittal Narayanan
- Source: IET Systems Biology, Volume 9, Issue 6, p. 309 –314
- DOI: 10.1049/iet-syb.2015.0012
- Type: Article
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Remote health monitoring system with clinical decision support system as a key component could potentially quicken the response of medical specialists to critical health emergencies experienced by their patients. A monitoring system, specifically designed for cardiac care with electrocardiogram (ECG) signal analysis as the core diagnostic technique, could play a vital role in early detection of a wide range of cardiac ailments, from a simple arrhythmia to life threatening conditions such as myocardial infarction. The system that the authors have developed consists of three major components, namely, (a) mobile gateway, deployed on patient's mobile device, that receives 12-lead ECG signals from any ECG sensor, (b) remote server component that hosts algorithms for accurate annotation and analysis of the ECG signal and (c) point of care device of the doctor to receive a diagnostic report from the server based on the analysis of ECG signals. In the present study, their focus has been toward developing a system capable of detecting critical cardiac events well in advance using an advanced remote monitoring system. A system of this kind is expected to have applications ranging from tracking wellness/fitness to detection of symptoms leading to fatal cardiac events.
Computational Models & Methods in Systems Biology & Medicine
Ant colony optimisation of decision tree and contingency table models for the discovery of gene–gene interactions
Computational approaches for understanding the diagnosis and treatment of Parkinson's disease
Deploying swarm intelligence in medical imaging identifying metastasis, micro-calcifications and brain image segmentation
Integrated dopaminergic neuronal model with reduced intracellular processes and inhibitory autoreceptors
Theoretical cross-comparative analysis on dynamics of small intestine and colon crypts during cancer initiation
Investigating receptor enzyme activity using time-scale analysis
Modelling the role of catastrophe, crossover and katanin-mediated severing in the self-organisation of plant cortical microtubules
Structural and practical identifiability analysis of S-system
In silico discovery of significant pathways in colorectal cancer metastasis using a two-stage optimisation approach
HeartSearcher: finds patients with similar arrhythmias based on heartbeat classification
Remote health monitoring system for detecting cardiac disorders
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