Localization of Function via Lesion Analysis

Aharonov, Ranit; Segev, Lior; Meilijson, Isaac; Ruppin, Eytan

doi:10.1162/08997660360581949

Cited by 39 publications

(70 citation statements)

References 34 publications

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“…Furthermore, following recent trends aiming at the study of computational models in lesion conditions [5,6], we adapt our method to accomplish systematic modelling of biological lesion experiments. Appropriate fitness functions indicate the performance of the model when all substructures are present, and they also indicate the performance when some partial structures are eliminated.…”

Section: Introductionmentioning

confidence: 99%

Modelling Robotic Cognitive Mechanisms by Hierarchical Cooperative Coevolution

Maniadakis

Trahanias

2007

Int. J. Artif. Intell. Tools

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Abstract. The current work addresses the development of cognitive abilities in artificial organisms. In the proposed approach, neural networkbased agent structures are employed to represent distinct brain areas. We introduce a Hierarchical Cooperative CoEvolutionary (HCCE) approach to design autonomous, yet collaborating agents. Thus, partial brain models consisting of many substructures can be designed. Replication of lesion studies is used as a means to increase reliability of brain model, highlighting the distinct roles of agents. The proposed approach effectively designs cooperating agents by considering the desired preand post-lesion performance of the model. In order to verify and assess the implemented model, the latter is embedded in a robotic platform to facilitate its behavioral capabilities.

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Section: Introductionmentioning

confidence: 99%

Modelling Robotic Cognitive Mechanisms by Hierarchical Cooperative Coevolution

Maniadakis

Trahanias

2007

Int. J. Artif. Intell. Tools

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“…These new methods are the first to utilize fundamental results from game theory to assess the contribution of system elements and functional subsets of such elements to the overall system performance function. For the task of determining the functional contribution of system elements, these game theory tools are more adequate than standard machine learning approaches employ-ing error minimization (e.g., [21]), since they are based on a solid axiomatic framework and provide a unique contribution assignment [16]. Recently, there have been a number of attempts to utilize game theory approaches in neuroscience, but these had a completely different goal of constructing decision-making models [22,23].…”

Section: Introductionmentioning

confidence: 99%

Quantitative Analysis of Genetic and Neuronal Multi-Perturbation Experiments

Kaufman¹,

Keinan²,

Meilijson³

et al. 2005

PLoS Comp Biol

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Perturbation studies, in which functional performance is measured after deletion, mutation, or lesion of elements of a biological system, have been traditionally employed in many fields in biology. The vast majority of these studies have been qualitative and have employed single perturbations, often resulting in little phenotypic effect. Recently, newly emerging experimental techniques have allowed researchers to carry out concomitant multi-perturbations and to uncover the causal functional contributions of system elements. This study presents a rigorous and quantitative multiperturbation analysis of gene knockout and neuronal ablation experiments. In both cases, a quantification of the elements' contributions, and new insights and predictions, are provided. Multi-perturbation analysis has a potentially wide range of applications and is gradually becoming an essential tool in biology.

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“…Furthermore, following recent trends aiming at the study of computational models in lesion conditions [11,12,13], we adapt our method to accomplish systematic modelling of biological lesion experiments. The agent-based representation of brain areas facilitates lesion simulation by simply deactivating appropriate agent structures.…”

Section: Introductionmentioning

confidence: 99%

Distributed Brain Modelling by means of Hierarchical Collaborative CoEvolution

Maniadakis

Trahanias

2005 IEEE Congress on Evolutionary Computation

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Abstract-The current work addresses the development of cognitive abilities in artificial organisms. In the proposed approach, neural network-based agent structures are employed to represent distinct brain areas. We introduce a Hierarchical Collaborative CoEvolutionary (HCCE) approach to design autonomous, yet cooperating agents. Thus, partial brain models consisting of many substructures can be designed. Replication of lesion studies is used as a means to increase reliability of brain model, highlighting the distinct roles of agents. The HCCE is appropriately designed to support systematic modelling of brain structures, able to reproduce biological lesion data. The proposed approach effectively designs cooperating agents by considering the desired pre-and post-lesion performance of the model. In order to verify and asses the implemented model, the latter is embedded in a robotic platform to facilitate its behavioral capabilities.

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Localization of Function via Lesion Analysis

Cited by 39 publications

References 34 publications

Modelling Robotic Cognitive Mechanisms by Hierarchical Cooperative Coevolution

Modelling Robotic Cognitive Mechanisms by Hierarchical Cooperative Coevolution

Quantitative Analysis of Genetic and Neuronal Multi-Perturbation Experiments

Distributed Brain Modelling by means of Hierarchical Collaborative CoEvolution

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