Sophisticated Transformers for Biomedical Text and Knowledge Graph Data
Project description
STonKGs
STonKGs is a Sophisticated Transformer that can be jointly trained on biomedical text and knowledge graphs. This multimodal Transformer combines structured information from KGs with unstructured text data to learn joint representations. While we demonstrated STonKGs on a biomedical knowledge graph ( i.e., from INDRA), the model can be applied other domains. In the following sections we describe the scripts that are necessary to be run to train the model on any given dataset.
💪 Getting Started
Data Format
Since STonKGs is operating on both text and KG data, it's expected that the respective data files include columns for
both modalities. More specifically, the expected data format is a pandas
dataframe (or a pickled pandas
dataframe
for the pre-training script), in which each row is containing one text-triple pair. The following columns are expected:
- source: Source node in the triple of a given text-triple pair
- target: Target node in the triple of a given text-triple pair
- evidence: Text of a given text-triple pair
- (optional) class: Class label for a given text-triple pair in fine-tuning tasks (does not apply to the pre-training procedure)
Note that both source and target nodes are required to be in the Biological Expression Langauge (BEL) format, more specifically, they need to be contained in the INDRA KG. For more details on the BEL format, see for example the INDRA documentation for BEL processor and PyBEL.
Pre-training STonKGs
Once you have installed STonKGs as a Python package (see below), you can start training the STonKGs on your dataset by running:
$ python3 -m stonkgs.models.stonkgs_pretraining
The configuration of the model can be easily modified by altering the parameters of the pretrain_stonkgs method. The only required argument to be changed is PRETRAINING_PREPROCESSED_POSITIVE_DF_PATH, which should point to your dataset.
Downloading the pre-trained STonKGs model on the INDRA KG
We released the pre-trained STonKGs models on the INDRA KG for possible future adaptations, such as further pre-training on other KGs. Both STonKGs150k as well as STonKGs300k are accessible through Hugging Face's model hub.
The easiest way to download and initialize the pre-trained STonKGs model is to use the from_default_pretrained()
class
method (with STonKGs150k being the default):
from stonkgs import STonKGsForPreTraining
# Download the model from the model hub and initialize it for pre-training
# using from_default_pretrained
stonkgs_pretraining = STonKGsForPreTraining.from_default_pretrained()
Alternatively, since our code is based on Hugging Face's transformers
package, the pre-trained model can be easily
downloaded and initialized using the .from_pretrained()
function:
from stonkgs import STonKGsForPreTraining
# Download the model from the model hub and initialize it for pre-training
# using from_pretrained
stonkgs_pretraining = STonKGsForPreTraining.from_pretrained(
'stonkgs/stonkgs-150k',
)
Extracting Embeddings
The learned embeddings of the pre-trained STonKGs models (or your own STonKGs variants) can be extracted in two simple
steps. First, a given dataset with text-triple pairs (a pandas DataFrame
, see Data Format) needs to be
preprocessed using the preprocess_file_for_embeddings
function. Then, one can obtain the learned embeddings using the
preprocessed data and the get_stonkgs_embeddings
function:
import pandas as pd
from stonkgs import get_stonkgs_embeddings, preprocess_df_for_embeddings
# Generate some example data
# Note that the evidence sentences are typically longer than in this example data
rows = [
[
"p(HGNC:1748 ! CDH1)",
"p(HGNC:2515 ! CTNND1)",
"Some example sentence about CDH1 and CTNND1.",
],
[
"p(HGNC:6871 ! MAPK1)",
"p(HGNC:6018 ! IL6)",
"Another example about some interaction between MAPK and IL6.",
],
[
"p(HGNC:3229 ! EGF)",
"p(HGNC:4066 ! GAB1)",
"One last example in which Gab1 and EGF are mentioned.",
],
]
example_df = pd.DataFrame(rows, columns=["source", "target", "evidence"])
# 1. Preprocess the text-triple data for embedding extraction
preprocessed_df_for_embeddings = preprocess_df_for_embeddings(example_df)
# 2. Extract the embeddings
embedding_df = get_stonkgs_embeddings(preprocessed_df_for_embeddings)
Fine-tuning STonKGs
The most straightforward way of fine-tuning STonKGs on the original six classfication tasks is to run the fine-tuning script (note that this script assumes that you have a mlflow logger specified, e.g. using the --logging_dir argument):
$ python3 -m stonkgs.models.stonkgs_finetuning
Moreover, using STonKGs for your own fine-tuning tasks (i.e., sequence classification tasks) in your own code is just as easy as initializing the pre-trained model:
from stonkgs import STonKGsForSequenceClassification
# Download the model from the model hub and initialize it for fine-tuning
stonkgs_model_finetuning = STonKGsForSequenceClassification.from_default_pretrained(
num_labels=number_of_labels_in_your_task,
)
# Initialize a Trainer based on the training dataset
trainer = Trainer(
model=model,
args=some_previously_defined_training_args,
train_dataset=some_previously_defined_finetuning_data,
)
# Fine-tune the model to the moon
trainer.train()
Using STonKGs for Inference
You can generate new predictions for previously unseen text-triple pairs (as long as the nodes are contained in the INDRA KG) based on either 1) the fine-tuned models used for the benchmark or 2) your own fine-tuned models. In order to do that, you first need to load/initialize the fine-tuned model:
from stonkgs.api import get_species_model, infer
model = get_species_model()
# Next, you want to use that model on your dataframe (consisting of at least source, target
# and evidence columns, see **Data Format**) to generate the class probabilities for each
# text-triple pair belonging to each of the specified classes in the respective fine-tuning task:
example_data = ...
# See Extracting Embeddings for the initialization of the example data
# This returns both the raw (transformers) PredictionOutput as well as the class probabilities
# for each text-triple pair
raw_results, probabilities = infer(model, example_data)
⬇️ Installation
The most recent release can be installed from PyPI with:
$ pip install stonkgs
The most recent code and data can be installed directly from GitHub with:
$ pip install git+https://github.com/stonkgs/stonkgs.git
To install in development mode, use the following:
$ git clone git+https://github.com/stonkgs/stonkgs.git
$ cd stonkgs
$ pip install -e .
Warning: Because stellargraph doesn't currently work on Python 3.9, this software can only be installed on Python 3.8.
Artifacts
The pre-trained models are hosted on HuggingFace The fine-tuned models are hosted on the STonKGs community page on Zenodo along with the other artifacts (node2vec embeddings, random walks, etc.)
Acknowledgements
⚖️ License
The code in this package is licensed under the MIT License.
📖 Citation
Balabin H., Hoyt C.T., Birkenbihl C., Gyori B.M., Bachman J.A., Komdaullil A.T., Plöger P.G., Hofmann-Apitius M., Domingo-Fernández D. STonKGs: A Sophisticated Transformer Trained on Biomedical Text and Knowledge Graphs (2021), bioRxiv, TODO.
🎁 Support
This project has been supported by several organizations (in alphabetical order):
- Fraunhofer Center for Machine Learning
- Harvard Program in Therapeutic Science - Laboratory of Systems Pharmacology
💰 Funding
This project has been funded by the following grants:
Funding Body | Program | Grant |
---|---|---|
DARPA | Automating Scientific Knowledge Extraction (ASKE) | HR00111990009 |
🍪 Cookiecutter
This package was created with @audreyfeldroy's cookiecutter package using @cthoyt's cookiecutter-snekpack template.
🛠️ Development
The final section of the README is for if you want to get involved by making a code contribution.
❓ Testing
After cloning the repository and installing tox
with pip install tox
, the unit tests in the tests/
folder can be
run reproducibly with:
$ tox
Additionally, these tests are automatically re-run with each commit in a GitHub Action.
📦 Making a Release
After installing the package in development mode and installing
tox
with pip install tox
, the commands for making a new release are contained within the finish
environment
in tox.ini
. Run the following from the shell:
$ tox -e finish
This script does the following:
- Uses BumpVersion to switch the version number in the
setup.cfg
andsrc/stonkgs/version.py
to not have the-dev
suffix - Packages the code in both a tar archive and a wheel
- Uploads to PyPI using
twine
. Be sure to have a.pypirc
file configured to avoid the need for manual input at this step - Push to GitHub. You'll need to make a release going with the commit where the version was bumped.
- Bump the version to the next patch. If you made big changes and want to bump the version by minor, you can
use
tox -e bumpversion minor
after.
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