Warfarin Dose Estimation on High-dimensional and Incomplete Data

Warfarin is a widely used oral anticoagulant worldwide. However, due to the complex relationship between individual factors, it is challenging to estimate the optimal warfarin dose to give full play to its ideal efficacy. Currently, there are plenty of studies using machine learning or deep learning techniques to help with the optimal warfarin dose selection. But few of them can resolve missing values and high-dimensional data naturally, that are two main concerns when analyzing clinical real world data. In this work, we propose to regard each patient’s record as a set of observed individual factors, and represent them in an embedding space, that enables our method can learn from the incomplete date directly and avoid the negative impact from the high-dimensional feature set. Then, a novel neural network is proposed to combine the set of embedded vectors non-linearly, that are capable of capturing their correlations and locating the informative ones for prediction. After comparing with the baseline models on the open source data from International Warfarin Pharmacogenetics Consortium, the experimental results demonstrate that our proposed method outperform others by a significant margin. After further analyzing the model performance in different dosing subgroups, we can conclude that the proposed method has the high application value in clinical, especially for the patients in high-dose and medium-dose subgroups

Clinical application of high throughput molecular screening techniques for pharmacogenomics.

Genetic analysis is one of the fastest-growing areas of clinical diagnostics. Fortunately, as our knowledge of clinically relevant genetic variants rapidly expands, so does our ability to detect these variants in patient samples. Increasing demand for genetic information may necessitate the use of high throughput diagnostic methods as part of clinically validated testing. Here we provide a general overview of our current and near-future abilities to perform large-scale genetic testing in the clinical laboratory. First we review in detail molecular methods used for high throughput mutation detection, including techniques able to monitor thousands of genetic variants for a single patient or to genotype a single genetic variant for thousands of patients simultaneously. These methods are analyzed in the context of pharmacogenomic testing in the clinical laboratories, with a focus on tests that are currently validated as well as those that hold strong promise for widespread clinical application in the near future. We further discuss the unique economic and clinical challenges posed by pharmacogenomic markers. Our ability to detect genetic variants frequently outstrips our ability to accurately interpret them in a clinical context, carrying implications both for test development and introduction into patient management algorithms. These complexities must be taken into account prior to the introduction of any pharmacogenomic biomarker into routine clinical testing

The future of laboratory medicine - A 2014 perspective.

Predicting the future is a difficult task. Not surprisingly, there are many examples and assumptions that have proved to be wrong. This review surveys the many predictions, beginning in 1887, about the future of laboratory medicine and its sub-specialties such as clinical chemistry and molecular pathology. It provides a commentary on the accuracy of the predictions and offers opinions on emerging technologies, economic factors and social developments that may play a role in shaping the future of laboratory medicine

Automatic Prediction of Rheumatoid Arthritis Disease Activity from the Electronic Medical Records

Objective: We aimed to mine the data in the Electronic Medical Record to automatically discover patients' Rheumatoid Arthritis disease activity at discrete rheumatology clinic visits. We cast the problem as a document classification task where the feature space includes concepts from the clinical narrative and lab values as stored in the Electronic Medical Record. Materials and Methods The Training Set consisted of 2792 clinical notes and associated lab values. Test Set 1 included 1749 clinical notes and associated lab values. Test Set 2 included 344 clinical notes for which there were no associated lab values. The Apache clinical Text Analysis and Knowledge Extraction System was used to analyze the text and transform it into informative features to be combined with relevant lab values. Results: Experiments over a range of machine learning algorithms and features were conducted. The best performing combination was linear kernel Support Vector Machines with Unified Medical Language System Concept Unique Identifier features with feature selection and lab values. The Area Under the Receiver Operating Characteristic Curve (AUC) is 0.831 (σ = 0.0317), statistically significant as compared to two baselines (AUC = 0.758, σ = 0.0291). Algorithms demonstrated superior performance on cases clinically defined as extreme categories of disease activity (Remission and High) compared to those defined as intermediate categories (Moderate and Low) and included laboratory data on inflammatory markers. Conclusion: Automatic Rheumatoid Arthritis disease activity discovery from Electronic Medical Record data is a learnable task approximating human performance. As a result, this approach might have several research applications, such as the identification of patients for genome-wide pharmacogenetic studies that require large sample sizes with precise definitions of disease activity and response to therapies

Pharmacogenetics to Avoid Adverse Drug Reactions

Adverse drug reactions are one of the major constraints when using drugs. These adverse reactions can impact healthcare systems as strongly as many prevalent diseases. Identifying DNA variants associated with adverse drug reactions can help personalize medicine and sustain healthcare systems. This book delves into new advances in pharmacogenetics of cardiovascular, cancer, and nervous system drugs. It may be useful for clinicians and patients to understand the basics of pharmacogenetics

Facilitating and Enhancing Biomedical Knowledge Translation: An in Silico Approach to Patient-centered Pharmacogenomic Outcomes Research

Current research paradigms such as traditional randomized control trials mostly rely on relatively narrow efficacy data which results in high internal validity and low external validity. Given this fact and the need to address many complex real-world healthcare questions in short periods of time, alternative research designs and approaches should be considered in translational research. In silico modeling studies, along with longitudinal observational studies, are considered as appropriate feasible means to address the slow pace of translational research. Taking into consideration this fact, there is a need for an approach that tests newly discovered genetic tests, via an in silico enhanced translational research model (iS-TR) to conduct patient-centered outcomes research and comparative effectiveness research studies (PCOR CER). In this dissertation, it was hypothesized that retrospective EMR analysis and subsequent mathematical modeling and simulation prediction could facilitate and accelerate the process of generating and translating pharmacogenomic knowledge on comparative effectiveness of anticoagulation treatment plan(s) tailored to well defined target populations which eventually results in a decrease in overall adverse risk and improve individual and population outcomes. To test this hypothesis, a simulation modeling framework (iS-TR) was proposed which takes advantage of the value of longitudinal electronic medical records (EMRs) to provide an effective approach to translate pharmacogenomic anticoagulation knowledge and conduct PCOR CER studies. The accuracy of the model was demonstrated by reproducing the outcomes of two major randomized clinical trials for individualizing warfarin dosing. A substantial, hospital healthcare use case that demonstrates the value of iS-TR when addressing real world anticoagulation PCOR CER challenges was also presented

Measuring Knowledge and Attitudes Regarding the Use of Pharmacogenetic Testing among Patients and Prescribers: Diffusion of Innovation Theory

Background: Healthcare providers play a key role in patient care. Their knowledge and attitudes may play a critical role in the incorporation of pharmacogenetic (PGx) testing into routine practice. The knowledge and attitudes of patients are also equally important in determining the rate of diffusion and the adoption of PGx testing. This study aims to test Rogers’s diffusion of innovation theory to identify and evaluate the influence of knowledge, attitudes, and sociodemographic characteristics of patients and physicians on the adoption of PGx testing in current clinical settings. Method: A cross-sectional, descriptive survey design was implemented. The sample consisted of patients with chronic diseases and licensed physicians. One-way analysis of variance (ANOVA), linear regression, and path analysis were performed to test the research hypotheses. Results: Limited knowledge regarding PGx testing was prevalent among patients, despite good attitudes. While the total PGx testing knowledge score was predicted significantly by levels of education, prior experience, and innovativeness, the total attitude score was predicted significantly by gender, relative advantage, compatibility, complexity, and trialability. The acceptance of PGx testing by patients was significantly influenced by their attitudes towards PGx testing and its perceived characteristics. Physicians expressed low levels of knowledge regarding PGx testing; however, the majority had favorable attitudes toward its potential clinical advantages. The total PGx testing knowledge score was predicted significantly by gender, type of practice setting, and prior experience. Physicians’ attitude score was predicted significantly by gender, relative advantage, and compatibility of PGx testing. Barriers to the adoption of PGx testing were reported. The acceptance of PGx testing by physicians was significantly influenced by the perceived characteristics of PGx testing and the perceived need for testing. Conclusion: This dissertation successfully evaluated the relationship among several factors adapted from Rogers’s theory and the adoption of PGx testing. The research is expected to provide the scientific community with an increased understanding of the decision-making process surrounding PGx testing. It will help identify the key factors and barriers that may have a significant influence on the direction of the future implementation of PGx testing, which will ultimately assist patients and physicians with therapeutic decisions

Bioinformaatika meetodid personaalses farmakoteraapias

Väitekirja elektrooniline versioon ei sisalda publikatsiooneKogutavate terviseandmete hulk kasvab kiiresti. Tänu neile andmetele on meditsiinilise ravi pakkumisel võimalik senisest enam arvesse võtta individuaalseid bioloogilisi andmeid. See doktoritöö käsitleb mitmeid personaalses meditsiinis esinevaid probleeme ja näitab, et ravi individualiseerimiseks kasutatavad andmed tulevad väga erinevatest allikatest. Inimestevahelised erinevused teevad ravimite metabolismi ennustamise keerukaks, siiski on ravi käigus kogutavad kontsentratsioonimõõtmised ravimiefekti hindamisel heaks allikaks. Me arendasime välja täppisdoseerimise tööriista, mis võimaldab vankomütsiini ravil vastsündinutele määrata ravi tõhustavat personaalseid doose kasutades selleks nende endi ravi käigus kogutud kontsentratsioone. Suurema osa ravimiteraapiate puhul ei ole võimalik pidevalt ravimi kontsentratsioone koguda. Nende ülejäänud ravimite puhul on heaks informatsiooniallikaks geneetika. Paljude ravimimetabolismiga seotud geneetiliste variantide mõju on piisav, et tingida muutuseid ravi läbiviimisel. Me uurisime geneetika ja ravimite kõrvalmõjude omavahelisi seoseid kasutades rahvastikupõhist lähenemist. See toetus Eesti Geenivaramu geeniandmetele ja teistele laiapõhjalistele terviseandmete registritele. Me leidsime ja valideerisime seose, et CTNNA3 geenis olev geenivariant tõstab oksikaamide ravil olevate inimeste jaoks kõrvalmõjude sagedust. Arvutuslik geneetika toetub kvantitatiivsetele meetoditele, millest kõige levinum on ülegenoomne assotsiatsiooni analüüs (GWAS). Sagedasti kasutatav GWASi järelsamm on aega nõudev GWASist ilmnenud p-väärtuste visuaalne hindamine teiste samas genoomi piirkonnas olevate geneetiliste variantide kontekstis. Selle sammu automatiseerimiseks arendasime me kaks tööriista, Manhattan Harvester ja Cropper, mis võimaldavad automaatselt huvipakkuvaid piirkondi tuvastada ja nende headust hinnata.The amount of collected health data is growing fast. Insights from these data allow using biological patient specifics to improve therapy management with further individualization. This thesis addresses problems in multiple sub-fields of personalised medicine and aims to illustrate that data for precision medicine emerges from different sources. Drug metabolism is difficult to predict because individual biological differences. Fortunately, drug concentrations are a good proxy for drug effect. To address the growing need for tools that allow on-line therapy adjustment based on individual concentrations we have developed and externally evaluated a precision dosing tool that allows individualised dosing of vancomycin in neonates. Other than drugs used in therapeutic drug monitoring, most pharmacotherapies can not rely on continuous concentration measurements but for such drugs genetics provides a valuable source of information for individualization. Effects of many genetic variants in drug metabolism pathways are often large enough to require changes in drug prescriptions or schedules. We have applied a population-based approach in testing relations between drug related adverse effects and genomic loci, and found and validated a novel variant in CTNNA3 gene that increases adverse drug effects in patients with oxicam prescriptions. This was done by leveraging the data in Estonian Genome Center and linking these to nation-wide electronic health data registries. Computational genetics relies on quantitative methods for which the most common is the genome-wide association analysis (GWAS). A common GWAS downstream step involves time-consuming visual assessment of the association study p-values in context with other variants in genomic vicinity. In order to streamline this step, we developed, Manhattan Harvester and Cropper, that allow for automated detection of peak areas and assign scores by emulating human evaluators.https://www.ester.ee/record=b524282