# coding=utf-8 # Copyright 2022 The HuggingFace Datasets Authors and the current dataset script contributor. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. """ A dataset loader for the n2c2 2018 Adverse Drug Events and Medication Extraction dataset. The dataset consists of multiple archive files two of which are being used by the script, ├── training_20180910.zip └── gold-standard-test-data.zip The individual data files (inside the zip and tar archives) come in 4 types, * docs (*.txt files): text of a patient record * annotations (*.ann files): entities and relations along with offsets used as input to a NER / RE model The files comprising this dataset must be on the users local machine in a single directory that is passed to `datasets.load_dataset` via the `data_dir` kwarg. This loader script will read the archive files directly (i.e. the user should not uncompress, untar or unzip any of the files). Data Access from https://portal.dbmi.hms.harvard.edu/projects/n2c2-nlp/ [bigbio_schema_name] = kb """ import os import zipfile from collections import defaultdict from typing import Dict, List, Tuple import datasets from .bigbiohub import kb_features from .bigbiohub import BigBioConfig from .bigbiohub import Tasks _LANGUAGES = ['English'] _PUBMED = False _LOCAL = True _CITATION = """\ @article{DBLP:journals/jamia/HenryBFSU20, author = { Sam Henry and Kevin Buchan and Michele Filannino and Amber Stubbs and Ozlem Uzuner }, title = {2018 n2c2 shared task on adverse drug events and medication extraction in electronic health records}, journal = {J. Am. Medical Informatics Assoc.}, volume = {27}, number = {1}, pages = {3--12}, year = {2020}, url = {https://doi.org/10.1093/jamia/ocz166}, doi = {10.1093/jamia/ocz166}, timestamp = {Sat, 30 May 2020 19:53:56 +0200}, biburl = {https://dblp.org/rec/journals/jamia/HenryBFSU20.bib}, bibsource = {dblp computer science bibliography, https://dblp.org} } """ _DATASETNAME = "n2c2_2018_track2" _DISPLAYNAME = "n2c2 2018 ADE" _DESCRIPTION = """\ The National NLP Clinical Challenges (n2c2), organized in 2018, continued the legacy of i2b2 (Informatics for Biology and the Bedside), adding 2 new tracks and 2 new sets of data to the shared tasks organized since 2006. Track 2 of 2018 n2c2 shared tasks focused on the extraction of medications, with their signature information, and adverse drug events (ADEs) from clinical narratives. This track built on our previous medication challenge, but added a special focus on ADEs. ADEs are injuries resulting from a medical intervention related to a drugs and can include allergic reactions, drug interactions, overdoses, and medication errors. Collectively, ADEs are estimated to account for 30% of all hospital adverse events; however, ADEs are preventable. Identifying potential drug interactions, overdoses, allergies, and errors at the point of care and alerting the caregivers of potential ADEs can improve health delivery, reduce the risk of ADEs, and improve health outcomes. A step in this direction requires processing narratives of clinical records that often elaborate on the medications given to a patient, as well as the known allergies, reactions, and adverse events of the patient. Extraction of this information from narratives complements the structured medication information that can be obtained from prescriptions, allowing a more thorough assessment of potential ADEs before they happen. The 2018 n2c2 shared task Track 2, hereon referred to as the ADE track, tackled these natural language processing tasks in 3 different steps, which we refer to as tasks: 1. Concept Extraction: identification of concepts related to medications, their signature information, and ADEs 2. Relation Classification: linking the previously mentioned concepts to their medication by identifying relations on gold standard concepts 3. End-to-End: building end-to-end systems that process raw narrative text to discover concepts and find relations of those concepts to their medications Shared tasks provide a venue for head-to-head comparison of systems developed for the same task and on the same data, allowing researchers to identify the state of the art in a particular task, learn from it, and build on it. """ _HOMEPAGE = "https://portal.dbmi.hms.harvard.edu/projects/n2c2-nlp/" _LICENSE = 'Data User Agreement' _SUPPORTED_TASKS = [Tasks.NAMED_ENTITY_RECOGNITION, Tasks.RELATION_EXTRACTION] _SOURCE_VERSION = "1.0.0" # 2018-09-10 _BIGBIO_VERSION = "1.0.0" # Constants DELIMITER = "||" SOURCE = "source" BIGBIO_KB = "bigbio_kb" ID = "id" ANNOTATIONS_EXT = "ann" TEXT, TEXT_EXT = "text", "txt" TAG, TAGS = "tag", "tags" RELATION, RELATIONS = "relation", "relations" START, END = "start", "end" N2C2_2018_NER_LABELS = sorted( [ "Drug", "Frequency", "Reason", "ADE", "Dosage", "Duration", "Form", "Route", "Strength", ] ) N2C2_2018_RELATION_LABELS = sorted( [ "Frequency-Drug", "Strength-Drug", "Route-Drug", "Dosage-Drug", "ADE-Drug", "Reason-Drug", "Duration-Drug", "Form-Drug", ] ) def _form_id(sample_id, entity_id, split): return "{}-{}-{}".format(sample_id, entity_id, split) def _build_concept_dict(tag_id, tag_start, tag_end, tag_type, tag_text): return { ID: tag_id, TEXT: tag_text, START: int(tag_start), END: int(tag_end), TAG: tag_type, } def _build_relation_dict(rel_id, arg1, arg2, rel_type): return { ID: rel_id, "arg1_id": arg1, "arg2_id": arg2, RELATION: rel_type, } def _get_annotations(annotation_file): """Return a dictionary with all the annotations in the .ann file. A typical line has either of the following form, 1. 'T41 Form 8977 8990 ophthalmology' -> ' ' 2. 'R22 Form-Drug Arg1:T41 Arg2:T40' -> ' ' """ tags, relations = {}, {} lines = annotation_file.splitlines() for line_num, line in enumerate(filter(lambda l: l.strip().startswith("T"), lines)): try: tag_id, tag_m, tag_text = line.strip().split("\t") except ValueError: print(line) if len(tag_m.split(" ")) == 3: tag_type, tag_start, tag_end = tag_m.split(" ") elif len(tag_m.split(" ")) == 4: tag_type, tag_start, _, tag_end = tag_m.split(" ") elif len(tag_m.split(" ")) == 5: tag_type, tag_start, _, _, tag_end = tag_m.split(" ") else: print(line) tags[tag_id] = _build_concept_dict( tag_id, tag_start, tag_end, tag_type, tag_text ) for line_num, line in enumerate(filter(lambda l: l.strip().startswith("R"), lines)): rel_id, rel_m = line.strip().split("\t") rel_type, rel_arg1, rel_arg2 = rel_m.split(" ") rel_arg1 = rel_arg1.split(":")[1] rel_arg2 = rel_arg2.split(":")[1] arg1 = tags[rel_arg1][ID] arg2 = tags[rel_arg2][ID] relations[rel_id] = _build_relation_dict(rel_id, arg1, arg2, rel_type) return tags.values(), relations.values() def _read_zip(file_path): samples = defaultdict(dict) with zipfile.ZipFile(file_path) as zf: for info in zf.infolist(): base, filename = os.path.split(info.filename) _, ext = os.path.splitext(filename) ext = ext[1:] # get rid of dot sample_id = filename.split(".")[0] if ext in [TEXT_EXT, ANNOTATIONS_EXT] and not filename.startswith("."): content = zf.read(info).decode("utf-8") if ext == TEXT_EXT: samples[sample_id][ext] = content else: ( samples[sample_id][TAGS], samples[sample_id][RELATIONS], ) = _get_annotations(content) return samples def _get_entities_from_sample(sample_id, sample, split): entities = [] entity_ids = set() text = sample[TEXT_EXT] for entity in sample[TAGS]: text_slice = text[entity[START] : entity[END]] text_slice_norm_1 = text_slice.replace("\n", "").lower() text_slice_norm_2 = text_slice.replace("\n", " ").lower() match = text_slice_norm_1 == entity[TEXT] or text_slice_norm_2 == entity[TEXT] if not match: continue entity_id = _form_id(sample_id, entity[ID], split) entity_ids.add(entity_id) entities.append( { ID: entity_id, "type": entity[TAG], TEXT: [text_slice], "offsets": [(entity[START], entity[END])], "normalized": [], } ) return entities, entity_ids def _get_relations_from_sample(sample_id, sample, split, entity_ids): """ A small number of relation from the *.ann files could not be aligned with the text and were excluded. For this reason we pass in the full set of matched entity IDs and ensure that no relations refers to an excluded entity. """ relations = [] for relation in sample[RELATIONS]: arg1_id = _form_id(sample_id, relation["arg1_id"], split) arg2_id = _form_id(sample_id, relation["arg2_id"], split) if arg1_id in entity_ids and arg2_id in entity_ids: relations.append( { ID: _form_id(sample_id, relation[ID], split), "type": relation[RELATION], "arg1_id": _form_id(sample_id, relation["arg1_id"], split), "arg2_id": _form_id(sample_id, relation["arg2_id"], split), "normalized": [], } ) return relations class N2C2AdverseDrugEventsMedicationExtractionDataset(datasets.GeneratorBasedBuilder): """n2c2 2018 Track 2 concept and relation task""" SOURCE_VERSION = datasets.Version(_SOURCE_VERSION) BIGBIO_VERSION = datasets.Version(_BIGBIO_VERSION) SOURCE_CONFIG_NAME = _DATASETNAME + "_" + SOURCE BIGBIO_CONFIG_NAME = _DATASETNAME + "_" + BIGBIO_KB BUILDER_CONFIGS = [ BigBioConfig( name=SOURCE_CONFIG_NAME, version=SOURCE_VERSION, description=_DATASETNAME + " source schema", schema=SOURCE, subset_id=_DATASETNAME, ), BigBioConfig( name=BIGBIO_CONFIG_NAME, version=BIGBIO_VERSION, description=_DATASETNAME + " BigBio schema", schema=BIGBIO_KB, subset_id=_DATASETNAME, ), ] DEFAULT_CONFIG_NAME = SOURCE_CONFIG_NAME def _info(self) -> datasets.DatasetInfo: if self.config.schema == SOURCE: features = datasets.Features( { "doc_id": datasets.Value("string"), TEXT: datasets.Value("string"), TAGS: [ { ID: datasets.Value("string"), TEXT: datasets.Value("string"), START: datasets.Value("int64"), END: datasets.Value("int64"), TAG: datasets.ClassLabel(names=N2C2_2018_NER_LABELS), } ], RELATIONS: [ { ID: datasets.Value("string"), "arg1_id": datasets.Value("string"), "arg2_id": datasets.Value("string"), RELATION: datasets.ClassLabel( names=N2C2_2018_RELATION_LABELS ), } ], } ) elif self.config.schema == BIGBIO_KB: features = kb_features return datasets.DatasetInfo( description=_DESCRIPTION, features=features, homepage=_HOMEPAGE, license=str(_LICENSE), citation=_CITATION, ) def _split_generators(self, dl_manager) -> List[datasets.SplitGenerator]: """Returns SplitGenerators.""" if self.config.data_dir is None or self.config.name is None: raise ValueError( "This is a local dataset. Please pass the data_dir and name kwarg to load_dataset." ) else: data_dir = self.config.data_dir return [ datasets.SplitGenerator( name=datasets.Split.TRAIN, gen_kwargs={ "file_path": os.path.join(data_dir, "training_20180910.zip"), "split": datasets.Split.TRAIN, }, ), datasets.SplitGenerator( name=datasets.Split.TEST, gen_kwargs={ "file_path": os.path.join(data_dir, "gold-standard-test-data.zip"), "split": datasets.Split.TEST, }, ), ] @staticmethod def _get_source_sample(sample_id, sample): return { "doc_id": sample_id, TEXT: sample.get(TEXT_EXT, ""), TAGS: sample.get(TAGS, []), RELATIONS: sample.get(RELATIONS, []), } @staticmethod def _get_bigbio_sample(sample_id, sample, split) -> dict: passage_text = sample.get("txt", "") entities, entity_ids = _get_entities_from_sample(sample_id, sample, split) relations = _get_relations_from_sample(sample_id, sample, split, entity_ids) return { "id": sample_id, "document_id": sample_id, "passages": [ { "id": f"{sample_id}-passage-0", "type": "discharge summary", "text": [passage_text], "offsets": [(0, len(passage_text))], } ], "entities": entities, "relations": relations, "events": [], "coreferences": [], } def _generate_examples(self, file_path, split: str) -> Tuple[int, Dict]: """Yields examples as (key, example) tuples.""" samples = _read_zip(file_path) _id = 0 for sample_id, sample in samples.items(): if ( self.config.name == N2C2AdverseDrugEventsMedicationExtractionDataset.SOURCE_CONFIG_NAME ): yield _id, self._get_source_sample(sample_id, sample) elif ( self.config.name == N2C2AdverseDrugEventsMedicationExtractionDataset.BIGBIO_CONFIG_NAME ): yield _id, self._get_bigbio_sample(sample_id, sample, split) _id += 1