This is a Keras implementation of the paper A Lightweight Neural Model for Biomedical Entity Linking.
Clone the repository and set up the environment via "requirements.txt". Here we use python3.6.
pip install -r requirements.txt
Dataset. It is not easy to collect all related data quickly. For your convenience, we provide a preprocessed version of datasets so that you could run our model straight. But there is a data license of the ShARe/CLEF dataset, we suggest you to obtain it according to an official guideline. We valid our model on three datasets, ShARe/CLEF, NCBI and ADR. Download these dataset and their corresponding knowledge bases following the urls below. | Dataset | Reference KB |
---|---|---|
NCBI disease | MEDIC (July 6, 2012) | |
ShARe/CLEF eHealth 2013 Challenge | SNOMED-CT (UMLS 2012AA) | |
TAC 2017 ADR | MedDRA (18.1) |
Word Embedding.
In our experiments, we represent each word by a 200-dimensional word embedding computed on PubMed and
MIMIC-III corpus, which is proposed in this paper[1]. Downlaod.
After downloading, put the embedding file in the path Biomedical-Entity-Linking/input/
Entity Embedding.
We provide pre-trained entity embeddings. You can find them in this path Biomedical-Entity-Linking/output/*dataset name*/embed/entity_emb_50.txt
Certain entities are more likely to occur together
in the same document than others, and we can leverage
this disposition to help the entity linking. To capture the
co-occurrence of entities, we pre-train entity embeddings in
such a way that entities that often co-occur together have
a similar distributed representation. We train these embeddings
with Word2Vec on a collection
of PubMed abstracts2. Since the entities in this corpus are
not linked to our KB, we consider every occurrence of an
exact entity name as a mention of that entity.
Here, the medical corpus we adopt is a collection of PubMed abstracts
which can be obtained at ftp://ftp.ncbi.nlm.nih.gov/pubmed/baseline/
First you can use -help
to show the arguments
python train.py -help
Once completing the data preparation and environment setup, we can evaluate the model via train.py
.
We have also provided datasets after preprocessing, you can just run the mode without downloading.
python3 train.py -dataset ncbi
Using Optimal Parameters
python train.py -dataset ncbi
python train.py -dataset clef -hinge 0.30 -alpha 0.6
python train.py -dataset adr
Adding Features
python train.py -dataset ncbi -add_prior True
python train.py -dataset ncbi -add_context True
python train.py -dataset ncbi -add_coherence True -voting_k 10
-voting_k 8 for ncbi
-voting_k 10 for adr
-voting_k 15 for ShARe/CLEF
@inproceedings{chen2021lightweight,
title={A Lightweight Neural Model for Biomedical Entity Linking},
author={Chen, Lihu and Varoquaux, Ga{\"e}l and Suchanek, Fabian},
booktitle={The Thirty-Fifth AAAI Conference on Artificial Intelligence},
number={35},
pages={14},
year={2021}
}
[1] Zhang Y, Chen Q, Yang Z, Lin H, Lu Z. BioWordVec, improving biomedical word embeddings with subword information and MeSH. Scientific Data. 2019.