Medizinische Universität Graz - Research portal

Go directly to the nagivation.
Go directly to the content.

Navigation/Search

"Faces" of the day:

Natalie Berger

Esther Föderl-Höbenreich

Doris Eglseer

Snjezana Radulovic

Natalie Bordag

Sayantanee Dutta

Magdalena Hoffmann

Sonja Hochmeister

Katrin Panzitt

Christine Moissl-Eichinger

Dajie Marschik

Kordula Lang-Illievich

Eva Maria Bernhart

Andrea Olschewski

Erika Richtig

Furkan Enes Oflaz

Michael Eichlseder

Johannes Pilic

Sascha Hammer

Markus Kneihsl

Simon Fandler-Höfler

Zhanat Koshenov

Martin Hirtl

Christoph Klivinyi

Benjamin Gottschalk

Philipp Zoidl

Vasile Foris

Matthias Gsell

Thomas Gattringer

Alexander Pichler

Thomas Eichmann

Nagaraj Chandran

Tobias Madl

Helmar Bornemann-Cimenti

Martin Urschler

Gabor Kovacs

Peter Marschik

Markus Waldeck-Weiermair

Leigh Marsh

René Rost

Michael Khalil

Christian Enzinger

Dirk von Lewinski

Roland Malli

Gerd Leitinger

Gernot Plank

Wolfgang Graier

Thomas Pieber

Selected Publication:

SHR Neuro Cancer Cardio Lipid Metab Microb

Pfeifer, B; Baniecki, H; Saranti, A; Biecek, P; Holzinger, A.
Multi-omics disease module detection with an explainable Greedy Decision Forest.
Sci Rep. 2022; 12(1): 16857 Doi: 10.1038/s41598-022-21417-8 [OPEN ACCESS]
Web of Science PubMed FullText FullText_MUG

Leading authors Med Uni Graz: Pfeifer Bastian
Co-authors Med Uni Graz: Holzinger Andreas; Saranti Anna
Altmetrics:
Dimensions Citations:
Plum Analytics:
Scite (citation analytics):
Abstract:: Machine learning methods can detect complex relationships between variables, but usually do not exploit domain knowledge. This is a limitation because in many scientific disciplines, such as systems biology, domain knowledge is available in the form of graphs or networks, and its use can improve model performance. We need network-based algorithms that are versatile and applicable in many research areas. In this work, we demonstrate subnetwork detection based on multi-modal node features using a novel Greedy Decision Forest (GDF) with inherent interpretability. The latter will be a crucial factor to retain experts and gain their trust in such algorithms. To demonstrate a concrete application example, we focus on bioinformatics, systems biology and particularly biomedicine, but the presented methodology is applicable in many other domains as well. Systems biology is a good example of a field in which statistical data-driven machine learning enables the analysis of large amounts of multi-modal biomedical data. This is important to reach the future goal of precision medicine, where the complexity of patients is modeled on a system level to best tailor medical decisions, health practices and therapies to the individual patient. Our proposed explainable approach can help to uncover disease-causing network modules from multi-omics data to better understand complex diseases such as cancer.