Challenges in biomarker discovery: combining expert insights with statistical analysis of complex omics data

McDermott, Jason; Wang, Jing; Mitchell, Hugh D.; Webb-Robertson, Bobbie-Jo M.; Hafen, Ryan; Ramey, John A.; Rodland, Karin D.

doi:10.1517/17530059.2012.718329

Cited by 167 publications

(102 citation statements)

References 93 publications

(102 reference statements)

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“…The big picture of the HCI-KDD approach: The horizontal process chain (blue box) encompasses the whole machine learning pipeline from physical aspects of raw data, to human aspects of data visualization; while the vertical topics (green box) include important aspects of structure (graphs/networks), space (computational topology) and time (entropy); privacy, data protection, safety and security are mandatory topics within the health domain and provide kind of a base compartment (Color figure online) (Image taken from hci-kdd.org) NGS etc. ), microarrays, transcriptomic technologies, proteomic and metabolomic technologies, etc., which all plays important roles for biomarker discovery and drug design [34,35]. (2) Clinical data (e.g.…”

Section: Research Track 1 Dat: Data Preprocessing Integration Fusionmentioning

confidence: 99%

Machine Learning for Health Informatics

Holzinger¹

2016

Lecture Notes in Computer Science

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Abstract. Machine Learning (ML) studies algorithms which can learn from data to gain knowledge from experience and to make decisions and predictions. Health Informatics (HI) studies the effective use of probabilistic information for decision making. The combination of both has greatest potential to rise quality, efficacy and efficiency of treatment and care. Health systems worldwide are confronted with "big data" in high dimensions, where the inclusion of a human is impossible and automatic ML (aML) show impressive results. However, sometimes we are confronted with complex data, "little data", or rare events, where aMLapproaches suffer of insufficient training samples. Here interactive ML (iML) may be of help, particularly with a doctor-in-the-loop, e.g. in subspace clustering, k-Anonymization, protein folding and protein design. However, successful application of ML for HI needs an integrated approach, fostering a concerted effort of four areas: (1) data science, (2) algorithms (with focus on networks and topology (structure), and entropy (time), (3) data visualization, and last but not least (4) privacy, data protection, safety & security.

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Section: Research Track 1 Dat: Data Preprocessing Integration Fusionmentioning

confidence: 99%

Machine Learning for Health Informatics

Holzinger¹

2016

Lecture Notes in Computer Science

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“…Since the beginning of the Human Genome Project [9], novel technological developments led to the era of omics sciences. Using novel high-throughput capturing technologies, we are now able to access the DNA of an individual (genetic data), the transcribed RNA over time (expression and co-expression data), proteins (protein profiles and protein interaction data), metabolism (metabolic profiles) and epigenome (DNA methylation data), among other data types [10]. The environment is also taken into account (e.g., nutrition and bacterial environment by nutriomics and metagenomics, respectively) [11,12], and also histopathological and medical imaging data are now subject to high throughput capturing and analysis methods [13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Integrative methods for analyzing big data in precision medicine

2016

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We provide an overview of recent developments in big data analyses in the context of precision medicine and health informatics. With the advance in technologies capturing molecular and medical data, we entered the area of Big Data in biology and medicine. These data offer many opportunities to advance precision medicine.We outline key challenges in precision medicine and present recent advances in data integrationbased methods to uncover personalized information from big data produced by various omics studies. We survey recent integrative methods for disease subtyping, bio-markers discovery and drug repurposing, and list the tools that are available to domain scientists. Given the ever-growing nature of these big data, we highlight key issues that big data integration methods will face.

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“…To prevent such disasters, a number of responses have been proposed. For example, some suggest that test development should use analytes with a plausible link to underlying biology (5 ). Others have advocated increased federal regulation, as exemplified by the recently proposed expansion in active oversight of laboratorydeveloped tests by the US Food and Drug Administration (6 ).…”

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confidence: 99%