Exploiting graph kernels for high performance biomedical relation extraction
Abstract Background Relation extraction from biomedical publications is an important task in the area of semantic mining of text. Kernel methods for supervised relation extraction are often preferred over manual feature engineering methods, when classifying highly ordered structures such as trees an...
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doaj-371acf6df19f4fafbba8d05ad6dec0432020-11-24T21:12:42ZengBMCJournal of Biomedical Semantics2041-14802018-01-019111110.1186/s13326-017-0168-3Exploiting graph kernels for high performance biomedical relation extractionNagesh C. Panyam0Karin Verspoor1Trevor Cohn2Kotagiri Ramamohanarao3School of Computing and Information Systems, University of MelbourneSchool of Computing and Information Systems, University of MelbourneSchool of Computing and Information Systems, University of MelbourneSchool of Computing and Information Systems, University of MelbourneAbstract Background Relation extraction from biomedical publications is an important task in the area of semantic mining of text. Kernel methods for supervised relation extraction are often preferred over manual feature engineering methods, when classifying highly ordered structures such as trees and graphs obtained from syntactic parsing of a sentence. Tree kernels such as the Subset Tree Kernel and Partial Tree Kernel have been shown to be effective for classifying constituency parse trees and basic dependency parse graphs of a sentence. Graph kernels such as the All Path Graph kernel (APG) and Approximate Subgraph Matching (ASM) kernel have been shown to be suitable for classifying general graphs with cycles, such as the enhanced dependency parse graph of a sentence. In this work, we present a high performance Chemical-Induced Disease (CID) relation extraction system. We present a comparative study of kernel methods for the CID task and also extend our study to the Protein-Protein Interaction (PPI) extraction task, an important biomedical relation extraction task. We discuss novel modifications to the ASM kernel to boost its performance and a method to apply graph kernels for extracting relations expressed in multiple sentences. Results Our system for CID relation extraction attains an F-score of 60%, without using external knowledge sources or task specific heuristic or rules. In comparison, the state of the art Chemical-Disease Relation Extraction system achieves an F-score of 56% using an ensemble of multiple machine learning methods, which is then boosted to 61% with a rule based system employing task specific post processing rules. For the CID task, graph kernels outperform tree kernels substantially, and the best performance is obtained with APG kernel that attains an F-score of 60%, followed by the ASM kernel at 57%. The performance difference between the ASM and APG kernels for CID sentence level relation extraction is not significant. In our evaluation of ASM for the PPI task, ASM performed better than APG kernel for the BioInfer dataset, in the Area Under Curve (AUC) measure (74% vs 69%). However, for all the other PPI datasets, namely AIMed, HPRD50, IEPA and LLL, ASM is substantially outperformed by the APG kernel in F-score and AUC measures. Conclusions We demonstrate a high performance Chemical Induced Disease relation extraction, without employing external knowledge sources or task specific heuristics. Our work shows that graph kernels are effective in extracting relations that are expressed in multiple sentences. We also show that the graph kernels, namely the ASM and APG kernels, substantially outperform the tree kernels. Among the graph kernels, we showed the ASM kernel as effective for biomedical relation extraction, with comparable performance to the APG kernel for datasets such as the CID-sentence level relation extraction and BioInfer in PPI. Overall, the APG kernel is shown to be significantly more accurate than the ASM kernel, achieving better performance on most datasets.http://link.springer.com/article/10.1186/s13326-017-0168-3Relation extractionGraph kernelsAPG kernelASM kernel |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Nagesh C. Panyam Karin Verspoor Trevor Cohn Kotagiri Ramamohanarao |
spellingShingle |
Nagesh C. Panyam Karin Verspoor Trevor Cohn Kotagiri Ramamohanarao Exploiting graph kernels for high performance biomedical relation extraction Journal of Biomedical Semantics Relation extraction Graph kernels APG kernel ASM kernel |
author_facet |
Nagesh C. Panyam Karin Verspoor Trevor Cohn Kotagiri Ramamohanarao |
author_sort |
Nagesh C. Panyam |
title |
Exploiting graph kernels for high performance biomedical relation extraction |
title_short |
Exploiting graph kernels for high performance biomedical relation extraction |
title_full |
Exploiting graph kernels for high performance biomedical relation extraction |
title_fullStr |
Exploiting graph kernels for high performance biomedical relation extraction |
title_full_unstemmed |
Exploiting graph kernels for high performance biomedical relation extraction |
title_sort |
exploiting graph kernels for high performance biomedical relation extraction |
publisher |
BMC |
series |
Journal of Biomedical Semantics |
issn |
2041-1480 |
publishDate |
2018-01-01 |
description |
Abstract Background Relation extraction from biomedical publications is an important task in the area of semantic mining of text. Kernel methods for supervised relation extraction are often preferred over manual feature engineering methods, when classifying highly ordered structures such as trees and graphs obtained from syntactic parsing of a sentence. Tree kernels such as the Subset Tree Kernel and Partial Tree Kernel have been shown to be effective for classifying constituency parse trees and basic dependency parse graphs of a sentence. Graph kernels such as the All Path Graph kernel (APG) and Approximate Subgraph Matching (ASM) kernel have been shown to be suitable for classifying general graphs with cycles, such as the enhanced dependency parse graph of a sentence. In this work, we present a high performance Chemical-Induced Disease (CID) relation extraction system. We present a comparative study of kernel methods for the CID task and also extend our study to the Protein-Protein Interaction (PPI) extraction task, an important biomedical relation extraction task. We discuss novel modifications to the ASM kernel to boost its performance and a method to apply graph kernels for extracting relations expressed in multiple sentences. Results Our system for CID relation extraction attains an F-score of 60%, without using external knowledge sources or task specific heuristic or rules. In comparison, the state of the art Chemical-Disease Relation Extraction system achieves an F-score of 56% using an ensemble of multiple machine learning methods, which is then boosted to 61% with a rule based system employing task specific post processing rules. For the CID task, graph kernels outperform tree kernels substantially, and the best performance is obtained with APG kernel that attains an F-score of 60%, followed by the ASM kernel at 57%. The performance difference between the ASM and APG kernels for CID sentence level relation extraction is not significant. In our evaluation of ASM for the PPI task, ASM performed better than APG kernel for the BioInfer dataset, in the Area Under Curve (AUC) measure (74% vs 69%). However, for all the other PPI datasets, namely AIMed, HPRD50, IEPA and LLL, ASM is substantially outperformed by the APG kernel in F-score and AUC measures. Conclusions We demonstrate a high performance Chemical Induced Disease relation extraction, without employing external knowledge sources or task specific heuristics. Our work shows that graph kernels are effective in extracting relations that are expressed in multiple sentences. We also show that the graph kernels, namely the ASM and APG kernels, substantially outperform the tree kernels. Among the graph kernels, we showed the ASM kernel as effective for biomedical relation extraction, with comparable performance to the APG kernel for datasets such as the CID-sentence level relation extraction and BioInfer in PPI. Overall, the APG kernel is shown to be significantly more accurate than the ASM kernel, achieving better performance on most datasets. |
topic |
Relation extraction Graph kernels APG kernel ASM kernel |
url |
http://link.springer.com/article/10.1186/s13326-017-0168-3 |
work_keys_str_mv |
AT nageshcpanyam exploitinggraphkernelsforhighperformancebiomedicalrelationextraction AT karinverspoor exploitinggraphkernelsforhighperformancebiomedicalrelationextraction AT trevorcohn exploitinggraphkernelsforhighperformancebiomedicalrelationextraction AT kotagiriramamohanarao exploitinggraphkernelsforhighperformancebiomedicalrelationextraction |
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