Cluster analysis in the COPDGene study identifies subtypes of smokers with distinct patterns of airway disease and emphysema

Castaldi, Peter J.; Dy, Jennifer G.; Ross, James C.; Chang, Yale; Washko, George R.; Curran‐Everett, Douglas; Williams, André; Lynch, David A.; Make, Barry J.; Crapo, James D.; Bowler, R.P.; Regan, Elizabeth A.; Hokanson, John E.; Kinney, Gregory L.; Han, MeiLan K.; Soler, Xavier; Ramsdell, Joseph W; Barr, R. Graham; Foreman, Marilyn G.; Beek, Edwin Jacques Rudolph van; Casaburi, Richard; Criner, G.J.; Lutz, Sharon M.; Rennard, S. I.; Santorico, Stephanie A.; Sciurba, Frank C.; DeMeo, Dawn L.; Hersh, Craig P.; Silverman, Edwin K.; Cho, Michael H.

doi:10.1136/thoraxjnl-2013-203601

Cited by 138 publications

(149 citation statements)

References 27 publications

Supporting

Mentioning

144

Contrasting

Order By: Relevance

“…In the field of personalised medicine, metabotyping may play a role by stratifying patients for the development of tailored healthcare solutions (45) . Examples of this concept are also available from the medical literature where cluster analysis has been used to identify different phenotypes for a range of diseases including chronic obstructive pulmonary disease (46) and Parkinsons disease (47) . This concept has been particularly useful for multisymtomatic and multifactorial diseases where presentation and severity of the disease can differ from one individual to the next.…”

Section: Moving From Individuals To Groups: a Novel Use Of Phenotypinmentioning

confidence: 99%

Can metabotyping help deliver the promise of personalised nutrition?

et al. 2015

View full text Add to dashboard Cite

Over a decade since the completion of the human genome sequence, the promise of personalised nutrition available to all has yet to become a reality. While the definition was originally very gene-focused, in recent years, a model of personalised nutrition has emerged with the incorporation of dietary, phenotypic and genotypic information at various levels. Developing on from the idea of personalised nutrition, the concept of targeted nutrition has evolved which refers to the delivery of tailored dietary advice at a group level rather than at an individual level. Central to this concept is metabotyping or metabolic phenotyping, which is the ability to group similar individuals together based on their metabolic or phenotypic profiles. Applications of the metabotyping concept extend from the nutrition to the medical literature. While there are many examples of the metabotype approach, there is a dearth in the literature with regard to the development of tailored interventions for groups of individuals. This review will first explore the effectiveness of personalised nutrition in motivating behaviour change and secondly, examine potential novel ways for the delivery of personalised advice at a population level through a metabotyping approach. Based on recent findings from our work, we will demonstrate a novel strategy for the delivery of tailored dietary advice at a group level using this concept. In general, there is a strong emerging evidence to support the effectiveness of personalised nutrition; future work should ascertain if targeted nutrition can motivate behaviour change in a similar manner.

show abstract

Section: Moving From Individuals To Groups: a Novel Use Of Phenotypinmentioning

confidence: 99%

Can metabotyping help deliver the promise of personalised nutrition?

et al. 2015

View full text Add to dashboard Cite

show abstract

“…They found that B-cell-related genes were significantly enriched in emphysema (compared with COPD patients without emphysema), paving the way for differential therapeutic research on inflammatory pathways of the adaptive immune response. 5) Two COPD studies demonstrated the utility of unsupervised k-means clustering by identifying robust cluster associations with clinical characteristics and known COPD genetic variants [95,96]. 6) Very recently, ROSS et al [97] introduced a new Bayesian method for COPD subtyping.…”

Section: Current Applications Of Systems Approaches In Respiratory Mementioning

confidence: 99%

From systems biology to P4 medicine: applications in respiratory medicine

2018

View full text Add to dashboard Cite

Human health and disease are emergent properties of a complex, nonlinear, dynamic multilevel biological system: the human body. Systems biology is a comprehensive research strategy that has the potential to understand these emergent properties holistically. It stems from advancements in medical diagnostics, "omics" data and bioinformatic computing power. It paves the way forward towards "P4 medicine" ( predictive, preventive, personalised and participatory), which seeks to better intervene preventively to preserve health or therapeutically to cure diseases. In this review, we: 1) discuss the principles of systems biology; 2) elaborate on how P4 medicine has the potential to shift healthcare from reactive medicine (treatment of illness) to predict and prevent illness, in a revolution that will be personalised in nature, probabilistic in essence and participatory driven; 3) review the current state of the art of network (systems) medicine in three prevalent respiratory diseases (chronic obstructive pulmonary disease, asthma and lung cancer); and 4) outline current challenges and future goals in the field.

show abstract

“…Although being called one disease, clinicians believe that COPD is a heterogeneous disease and the discovery of different disease subtypes (clusters) can lead to tailored medical care for each patient [1]. The dataset we use consists of a wide range of features extracted from patients, including their demographics, clinical information, lung function measurements, and variables extracted from computed tomography (CT) chest images.…”

Section: Motivating Problem: Disease Subtypingmentioning

confidence: 99%

“…In a recent seminal work [1], instead of manually defining COPD subtypes, some COPD investigators apply K-means clustering using a feature set they consider as important and generate a clustering solution that has significant association with some key genetic variables. This work demonstrates that it is possible to define meaningful COPD subtypes using data-driven approaches, such as clustering algorithms.…”

Section: Goldmentioning

confidence: 99%

See 1 more Smart Citation

Clustering with flexible constraints and application to disease subtyping

Chang¹

View full text Add to dashboard Cite

Cluster analysis in the COPDGene study identifies subtypes of smokers with distinct patterns of airway disease and emphysema

Cited by 138 publications

References 27 publications

Can metabotyping help deliver the promise of personalised nutrition?

Can metabotyping help deliver the promise of personalised nutrition?

From systems biology to P4 medicine: applications in respiratory medicine

Clustering with flexible constraints and application to disease subtyping

Contact Info

Product

Resources

About