BioM-Transformers: Building Large Biomedical Language Models with BERT, ALBERT and ELECTRA Abstract The impact of design choices on the performance of biomedical language models recently has been a subject for investigation. In this paper, we empirically study biomedical domain adaptation with large transformer models using different design choices. We evaluate the performance of our pretrained models against other existing biomedical language models in the literature. Our results show that we achieve state-of-the-art results on several biomedical domain tasks despite using similar or less computational cost compared to other models in the literature. Our findings highlight the significant effect of design choices on improving the performance of biomedical language models. This model is fine-tuned on the SQuAD2.0 dataset. Fine-tuning the biomedical language model on the SQuAD dataset helps improve the score on the BioASQ challenge. If you plan to work with BioASQ or biomedical QA tasks, it's better to use this model over BioM-ELECTRA-Large. This model (TensorFlow version ) took the lead in the BioASQ9b-Factoid challenge under the name of (UDEL-LAB2). To see the full details of BioASQ9B results, please check this link http://participants-area.bioasq.org/results/9b/phaseB/ ( you need to register). Huggingface library doesn't implement Layer-Wise decay feature, which affects the performance on SQuAD task. The reported result of BioM-ELECTRA-SQuAD in our paper is 88.3 (F1) since we use ELECTRA open-source code with TF checkpoint, which uses Layer-Wise decay. Evaluation results on SQuAD2.0 Dev Dataset ``` exact = 84.33420365535248 f1 = 87.49354241889522 total = 11873 HasAns_exact = 80.43184885290148 HasAns_f1 = 86.75958656200127 HasAns_total = 5928 NoAns_exact = 88.22539949537426 NoAns_f1 = 88.22539949537426 NoAns_total = 5945 best_exact = 84.33420365535248 best_exact_thresh = 0.0 best_f1 = 87.49354241889522 best_f1_thresh = 0.0 epoch = 2.0 ``` To reproduce results in Google Colab: - Make sure you have GPU enabled. - Clone and install required libraries through this code !git clone https://github.com/huggingface/transformers !pip3 install -e transformers !pip3 install sentencepiece !pip3 install -r /content/transformers/examples/pytorch/question-answering/requirements.txt - Run this python code: ```python python /content/transformers/examples/pytorch/question-answering/run_qa.py --model_name_or_path sultan/BioM-ELECTRA-Large-SQuAD2 \\ --do_eval \\ --version_2_with_negative \\ --per_device_eval_batch_size 8 \\ --dataset_name squad_v2 \\ --overwrite_output_dir \\ --fp16 \\ --output_dir out ``` You don't need to download the SQuAD2 dataset. The code will download it from the HuggingFace datasets hub. Check our GitHub repo at https://github.com/salrowili/BioM-Transformers for TensorFlow and GluonNLP Citation ```bibtex @inproceedings{alrowili-shanker-2021-biom, title = "{B}io{M}-Transformers: Building Large Biomedical Language Models with {BERT}, {ALBERT} and {ELECTRA}", author = "Alrowili, Sultan and Shanker, Vijay", booktitle = "Proceedings of the 20th Workshop on Biomedical Language Processing", month = jun, year = "2021", address = "Online", publisher = "Association for Computational Linguistics", url = "https://www.aclweb.org/anthology/2021.bionlp-1.24", pages = "221--227", abstract = "The impact of design choices on the performance of biomedical language models recently has been a subject for investigation. In this paper, we empirically study biomedical domain adaptation with large transformer models using different design choices. We evaluate the performance of our pretrained models against other existing biomedical language models in the literature. Our results show that we achieve state-of-the-art results on several biomedical domain tasks despite using similar or less computational cost compared to other models in the literature. Our findings highlight the significant effect of design choices on improving the performance of biomedical language models.", } ```