AI4D blog series: Improving Pharmacovigilance Systems using Natural Language Processing on Electronic Medical Records

This research focuses on enhancing Pharmacovigilance Systems using Natural Language Processing on Electronic Medical Records (EMR). Our major task was to develop an NLP model for extracting Adverse Drug Reaction(ADR) cases from EMR. The team was required to collect data from two hospitals, which are using EMR systems (i.e. University of Dodoma (UDOM) Hospital and Benjamin Mkapa (BM) Hospital). During data collection and analysis, we worked with health professionals from the two mentioned hospitals in Dodoma. We also used the public dataset from the MIMIC-III database. These datasets were presented in different formats, CSV for UDOM hospital and MIMIC III and PDF for BM hospital as shown on the attached file.

Team during an interview with Pharmacologist in BM hospital
Team during an interview with Pharmacologist in BM hospital

In most cases, pharmacovigilance practices depend on analyzing clinical trials, biomedical writing, observational examinations, Electronic Health Records (EHRs), Spontaneous Reporting (SR) and social media (Harpaz et al., 2014). As to our context, we considered EMR to be more informative compared to other practices, as suggested by (Luo et al., 2017). We studied schemas of EMRs from the two hospitals. We collected inpatients’ data since outpatients’ would have given the incomplete patient history. Also, our health information systems are not integrated, which makes it difficult to track patients’ full history unless patients were admitted to a particular hospital for a while. From all the data sources used there was a pattern of information that we were looking for, and this included clinical history, prior patient history, symptoms developed, allergies/ ADRs discovered during medication and patient’s discharge summary.

Much as we worked on UDOM and BM hospitals’ data, we encountered several challenges that made the team focus on MIMIC-III dataset while searching for an alternative way to our local data. Here were the challenges noted:

  • The reports had no clear identification of ADR cases.
  • In most cases, the doctor did not mention the reasons for changing a medicine on a particular patient which made it hard to understand whether the medication didn’t work well for a specific patient or any other reasons like adverse reaction.
  • The justification for ADR cases was vague
  • Mismatch of information between patients and doctors
  • The patients talk in a way that doctor can’t understand
  • There is a considerable gap between the health workers and regulatory authorities (They don’t know if they have to report for ADR cases)
  • The issue of ADR is so complex since there is a lot to take into account like Drug to Drug, Drug to food and Drug to herbal interactions.
  • There was no common/consistent reporting style among doctors
  • The language used to report is hard for a non-specialist to understand.
  • Some fields were left empty with no single information which led to incomplete medical history
  • The annotation process prolonged since we had one pharmacologist for the work.

After noticing all these challenges, the team carefully studied the MIMIC-III database to assess the availability of the data with ADR cases which would help to come up with the baseline model to the problem. We discovered that the NoteEvent table has enough information about the patient history with all clear indications of ADR cases and with no ADR see the text.

To start with, we were able to query 100,000 records from the database with many attributes, but we used a text column found in the NoteEvent table with the entire patient’s history including (patient’s prior history, medication, dosage, examination, changes noted during medications, symptoms etc.). We started the annotation of the first group by filtering the records to remain with the rows of interest. We used the following keywords in the search; adverse, reaction, adverse events, adverse reaction and reactions. We discovered that only 3446 rows contain words that guided the team in the labelling process. The records were then annotated with the labels 1 and 0 for ADR and non-ADR cases respectively, as indicated in the filtration notebook.

In analysing the data, we found that there were more non-ADR cases than ADR cases, in which non-ADR cases were 3199 and 228 ADR cases and 19 data rows not annotated. Due to high data imbalance, we reduced Non-ADR cases to 1000, and we applied sampling techniques (i.e upsampling ADR cases to 800) to at least balance the classes to minimize bias during modelling.

After annotation and simple analysis we used NLTK to apply the basic preprocessing techniques for text corpus as follows:-

  1. Converting the corpus-raw sentences to lower cases which helps in other processing techniques like parsing.
  2. Sentence tokenization, due to the text being in paragraphs, we applied sentence boundary detection to segment text to sentence level by identifying sentence starting point and endpoint.

Then we worked with regular contextual expressions to extract information of interest from the documents by removing some of the unnecessary characters and replacing some with easily understandable statements or characters as for professional guidelines.

We removed affixes in tokens which put words/tokens into their root form. Also, we removed common words(stopwords) and applied lemmatization to identify the correct part of speech(s) in the raw text. After data preprocessing, we used Term Frequency Inverse Document Frequency (TF-IDF) from scikit-learn to vectorize the corpus, which also gives the best exact keywords in the corpus.

In modelling to create a baseline model, we worked with classification algorithms using scikit-learn. We trained six different models which are Support Vector Machines, eXtreme Gradient Boosting, Adaptive Gradient Boosting , Decision Trees, Multilayer Perceptron and Random Forest  and then we selected three (Support Vector Machine, Multilayer Perceptron and Random Forest )models which performed better on validation compared to other  models for further model evaluation. We’ll also use the deep learning approach in the next phase of the project to produce more promising results for the model to be deployed and kept in practice. Here is the link to colab for data pre-processing and modelling.

From the UDOM database, we collected a total of 41,847 patient records in chunks of 16185, 18400, and 7262 from 2017 to 2019 respectively. The dataset has following attributes (Date, Admission number, Patient Age, Sex, Height(Kg), Allergy status, Examination, Registration ID, Patient History, Diagnosis, and Medication ), we downsized it to 12,708 records by removing missing columns and uninformative rows. We used regular contextual expressions to extract information of interest from the documents as for professional guidelines. The data cleaned and exchanged data formatting, analyzing and preparing data for machine learning was elaborated in this Colab link.

On the BM hospital, the PDF files extracted from EMS have patient records with the following information.

  1. Discharge reports
  2. Medical notes
  3. Patients history
  4. Lab notes

Health professionals on the respective hospitals manually annotated the labels for each document, and this task took most of our time in this phase of the project. We’re still collecting and interpreting more data from these hospitals.

The team organizes and extracts information from BM hospital PDF files by exchanging data formatting, analyzing and preparing data for machine learning. We experimented with OCR processing for PDF files to extract data, but we didn’t generate promising results as more information appeared to be missing. We therefore hard to programmatically remove content from individual files and align them to the corresponding professional provided labels.

The big lesson that we have learned up to now is that most of the data stored in our local systems are not informative. Policymakers must set standards to guide system developers during development and health practitioners when using the system.

Lastly but not least, we want to thank our stakeholders, mentors and funders for your involvement in our research activities. It is because of such a partnership we can be able to achieve our main goal.

Reposted within the project “Network of Excellence in Artificial Intelligence for Development (AI4D) in sub-Saharan Africa” #UnitedNations #artificialintelligence #SDG #UNESCO #videolectures #AI4DNetwork #AI4Dev #AI4D

AI4D blog series: Creating a ground truth dataset for malaria diagnosis in Tanzania

So why have we decided to collect malaria datasets to assist in developing a solution in its diagnosis? First, Malaria remains one of the significant threats to public health and economic development in Africa. Globally, it is estimated that 216 million cases of malaria occurred in 2017, with Africa bearing the brunt of this burden [5*]. In Tanzania, malaria is the leading cause of morbidity and mortality, especially in children under 5 years and pregnant women. Malaria kills one child every 30 seconds, about 3000 children every day [4*]. Malaria is also the leading cause of outpatients, inpatients, and admissions of children less than five years of age at health facilities [5*].

Second, the most common methods to test for malaria are microscopy and Rapid Diagnostic Tests (RDT) [1, 2]. RDTs are widely used, but their chief drawback is that they cannot count the number of parasites. The gold standard for the diagnosis of malaria is, therefore, microscopy. Evaluation of Giemsa-stained thick blood smears, when performed by expert microscopists, provides an accurate diagnosis of malaria [3].

Nonetheless, there are challenges to this method, it consumes a lot of time to perform one diagnosis, requires experienced technologists who are very few in developing countries, and manually looking at the sample via a microscope is a tedious and eye-straining process. We learned that although a microscopic diagnostic is a golden standard for malaria diagnosis, it is still not used in most of the private and public health centers. We realized that some of the lab technologists in health care are not competent in preparing staining reagents used in the diagnosis process. We had to create our own reagents and supply to them for the purpose of this research.

Artificial intelligence is transforming how health care is delivered across the world. This has been evident in pathology detection, surgery assistance and early detection of diseases such as breast cancer. However, these technologies often require significant amounts of quality data and in many developing countries, there is a shortage of this.

To address this deficiency, my team, composed of 6 computer scientists and 3 lab technologists, collected and annotated 10,000 images of a stained blood smear and developed an open-source annotation tool for the creation of a malaria dataset. We strongly believe the availability of more datasets and the annotation tool (for automating the labeling of the parasites in an image of stained blood smear) will improve the existing algorithms in malaria diagnosis and create a new benchmark.

In the collection of this dataset, we first sought and were granted ethical clearance from the University of Dodoma and Benjamin Mkapa Hospital’s research center. We have collected 50 blood smear samples for patients confirmed with malaria and 50 samples for negative confirmed cases. Each sample was stained by the lab technologist and 100 images were taken using iPhone 6S attached to a microscope. This led to having a total of 5000 images for the positive confirmed patients and 5000 imaged for the negative confirmed patient.

Through this work, we have had several opportunities including attending academic conferences and forming connections with other researchers such as Dr. Tom Neumark, a postdoctoral social anthropologist at the University of Oslo. Through our work, we also met Prof Delmiro Fernandes-Reyes, a professor of biomedical engineering. In a joint venture with Prof Delmiro Fernandes-Reyes, we submitted a proposal for the DIDA Stage 1 African Digital Pathology Artificial Intelligence Innovation Network (AfroDiPAI) at the end of November 2019.

We are also disseminating the results of our research. We have submitted an abstract (on the ongoing project) to two workshops (Practical Machine Learning in Developing Countries and Artificial Intelligence for Affordable Health) for the 2020 ICLR conference in Ethiopia, and it has been accepted to be presented as a poster. We were also delighted to get very constructive feedback from reviewers of the conference and look forward to incorporating them as we continue with the projects and final publication.

The next stage will be to start using our data and train deep learning models in the development of the open-source annotation tool. At the same time, together with the AI4D team, we are looking for the best approach to follow when releasing our open-source dataset in the medical field.

But our overall aim is to develop a final product of our mobile application that will assist lab technologist in Tanzania and beyond in the onerous work of diagnosis malaria. We have already met many of these technologists who are not only excited and eagerly awaiting this tool, but generously helped us as we have gone about developing it.

Links

[1] B.B. Andrade, A. Reis-Filho, A.M. Barros, S.M. Souza-Neto, L.L. Nogueira, K.F. Fukutani, E.P. Camargo, L.M.A. Camargo, A. Barral, A. Duarte, and M. Barral-Netto. Towards a precise test for malaria diagnosis in the Brazilian Amazon: comparison among field microscopy, a rapid diagnostic test, nested PCR, and a computational expert system based on artificial neural networks. Malaria Journal, 9:117, 2010.

[2]Maysa Mohamed Kamel, Samar Sayed Attia, Gomaa Desoky Emam, and Naglaa Abd El Khalek Al Sherbiny, “The Validity of Rapid Malaria Test and Microscopy in Detecting Malaria in a Preelimination Region of Egypt,” Scientifica, vol. 2016, Article ID 4048032, 5 pages, 2016. https://doi.org/10.1155/2016/4048032.

[3]Philip J. Rosenthal​*, “How Do We Best Diagnose Malaria in Africa?”: https://doi.org/10.4269/ajtmh.2012.11-0619

[12] UNICEF 2018 Report.   The urgent need to end newborn deaths. The reality of Malaria Summary https://www.unicef.org/health/files/health_africamalaria.pdf

[13]WHO malaria 2018 report. Retrieved on 1st March 2019 from  https://apps.who.int/iris/bitstream/handle/10665/275867/9789241565653-eng.pdf?ua=1

Reposted within the project “Network of Excellence in Artificial Intelligence for Development (AI4D) in sub-Saharan Africa” #UnitedNations #artificialintelligence #SDG #UNESCO #videolectures #AI4DNetwork #AI4Dev #AI4D