Urinary peptidomic liquid biopsy for non-invasive differential diagnosis of chronic kidney disease

Emmanouil Mavrogeorgis; Tianlin He; Harald Mischak; Agnieszka Latosinska; Antonia Vlahou; Joost P Schanstra; Lorenzo Catanese; Kerstin Amann; Tobias B Huber; Joachim Beige; Harald Rupprecht; Justyna Siwy

doi:10.1093/ndt/gfad200

Urinary peptidomic liquid biopsy for non-invasive differential diagnosis of chronic kidney disease

Standard

Urinary peptidomic liquid biopsy for non-invasive differential diagnosis of chronic kidney disease. / Mavrogeorgis, Emmanouil; He, Tianlin; Mischak, Harald; Latosinska, Agnieszka; Vlahou, Antonia; Schanstra, Joost P; Catanese, Lorenzo; Amann, Kerstin; Huber, Tobias B; Beige, Joachim; Rupprecht, Harald; Siwy, Justyna.

in: NEPHROL DIAL TRANSPL, Jahrgang 39, Nr. 3, 28.02.2024, S. 453-462.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Mavrogeorgis, E, He, T, Mischak, H, Latosinska, A, Vlahou, A, Schanstra, JP, Catanese, L, Amann, K, Huber, TB, Beige, J, Rupprecht, H & Siwy, J 2024, 'Urinary peptidomic liquid biopsy for non-invasive differential diagnosis of chronic kidney disease', NEPHROL DIAL TRANSPL, Jg. 39, Nr. 3, S. 453-462. https://doi.org/10.1093/ndt/gfad200

APA

Mavrogeorgis, E., He, T., Mischak, H., Latosinska, A., Vlahou, A., Schanstra, J. P., Catanese, L., Amann, K., Huber, T. B., Beige, J., Rupprecht, H., & Siwy, J. (2024). Urinary peptidomic liquid biopsy for non-invasive differential diagnosis of chronic kidney disease. NEPHROL DIAL TRANSPL, 39(3), 453-462. https://doi.org/10.1093/ndt/gfad200

Vancouver

Mavrogeorgis E, He T, Mischak H, Latosinska A, Vlahou A, Schanstra JP et al. Urinary peptidomic liquid biopsy for non-invasive differential diagnosis of chronic kidney disease. NEPHROL DIAL TRANSPL. 2024 Feb 28;39(3):453-462. https://doi.org/10.1093/ndt/gfad200

Bibtex

@article{0a150491925648e3adbcd9fad522e73c,

title = "Urinary peptidomic liquid biopsy for non-invasive differential diagnosis of chronic kidney disease",

abstract = "BACKGROUND AND HYPOTHESIS: Specific urinary peptides hold information on disease pathophysiology, which, in combination with artificial intelligence, could enable non-invasive assessment of chronic kidney disease (CKD) aetiology. Existing approaches are generally specific for the diagnosis of single aetiologies. We present the development of models able to simultaneously distinguish and spatially visualize multiple CKD aetiologies.METHODS: The urinary peptide data of 1850 healthy control (HC) and CKD [diabetic kidney disease (DKD), immunoglobulin A nephropathy (IgAN) and vasculitis] participants were extracted from the Human Urinary Proteome Database. Uniform manifold approximation and projection (UMAP) coupled to a support vector machine algorithm was used to generate multi-peptide models to perform binary (DKD, HC) and multiclass (DKD, HC, IgAN, vasculitis) classifications. This pipeline was compared with the current state-of-the-art single-aetiology CKD urinary peptide models.RESULTS: In an independent test set, the developed models achieved 90.35% and 70.13% overall predictive accuracies, respectively, for the binary and the multiclass classifications. Omitting the UMAP step led to improved predictive accuracies (96.14% and 85.06%, respectively). As expected, the HC class was distinguished with the highest accuracy. The different classes displayed a tendency to form distinct clusters in the 3D space based on their disease state.CONCLUSION: Urinary peptide data present an effective basis for CKD aetiology differentiation using machine learning models. Although adding the UMAP step to the models did not improve prediction accuracy, it may provide a unique visualization advantage. Additional studies are warranted to further validate the pipeline's clinical potential as well as to expand it to other CKD aetiologies and also other diseases.",

author = "Emmanouil Mavrogeorgis and Tianlin He and Harald Mischak and Agnieszka Latosinska and Antonia Vlahou and Schanstra, {Joost P} and Lorenzo Catanese and Kerstin Amann and Huber, {Tobias B} and Joachim Beige and Harald Rupprecht and Justyna Siwy",

note = "{\textcopyright} The Author(s) 2023. Published by Oxford University Press on behalf of the ERA.",

year = "2024",

month = feb,

day = "28",

doi = "10.1093/ndt/gfad200",

language = "English",

volume = "39",

pages = "453--462",

journal = "NEPHROL DIAL TRANSPL",

issn = "0931-0509",

publisher = "Oxford University Press",

number = "3",

}

RIS

TY - JOUR

T1 - Urinary peptidomic liquid biopsy for non-invasive differential diagnosis of chronic kidney disease

AU - Mavrogeorgis, Emmanouil

AU - He, Tianlin

AU - Mischak, Harald

AU - Latosinska, Agnieszka

AU - Vlahou, Antonia

AU - Schanstra, Joost P

AU - Catanese, Lorenzo

AU - Amann, Kerstin

AU - Huber, Tobias B

AU - Beige, Joachim

AU - Rupprecht, Harald

AU - Siwy, Justyna

PY - 2024/2/28

Y1 - 2024/2/28

N2 - BACKGROUND AND HYPOTHESIS: Specific urinary peptides hold information on disease pathophysiology, which, in combination with artificial intelligence, could enable non-invasive assessment of chronic kidney disease (CKD) aetiology. Existing approaches are generally specific for the diagnosis of single aetiologies. We present the development of models able to simultaneously distinguish and spatially visualize multiple CKD aetiologies.METHODS: The urinary peptide data of 1850 healthy control (HC) and CKD [diabetic kidney disease (DKD), immunoglobulin A nephropathy (IgAN) and vasculitis] participants were extracted from the Human Urinary Proteome Database. Uniform manifold approximation and projection (UMAP) coupled to a support vector machine algorithm was used to generate multi-peptide models to perform binary (DKD, HC) and multiclass (DKD, HC, IgAN, vasculitis) classifications. This pipeline was compared with the current state-of-the-art single-aetiology CKD urinary peptide models.RESULTS: In an independent test set, the developed models achieved 90.35% and 70.13% overall predictive accuracies, respectively, for the binary and the multiclass classifications. Omitting the UMAP step led to improved predictive accuracies (96.14% and 85.06%, respectively). As expected, the HC class was distinguished with the highest accuracy. The different classes displayed a tendency to form distinct clusters in the 3D space based on their disease state.CONCLUSION: Urinary peptide data present an effective basis for CKD aetiology differentiation using machine learning models. Although adding the UMAP step to the models did not improve prediction accuracy, it may provide a unique visualization advantage. Additional studies are warranted to further validate the pipeline's clinical potential as well as to expand it to other CKD aetiologies and also other diseases.

AB - BACKGROUND AND HYPOTHESIS: Specific urinary peptides hold information on disease pathophysiology, which, in combination with artificial intelligence, could enable non-invasive assessment of chronic kidney disease (CKD) aetiology. Existing approaches are generally specific for the diagnosis of single aetiologies. We present the development of models able to simultaneously distinguish and spatially visualize multiple CKD aetiologies.METHODS: The urinary peptide data of 1850 healthy control (HC) and CKD [diabetic kidney disease (DKD), immunoglobulin A nephropathy (IgAN) and vasculitis] participants were extracted from the Human Urinary Proteome Database. Uniform manifold approximation and projection (UMAP) coupled to a support vector machine algorithm was used to generate multi-peptide models to perform binary (DKD, HC) and multiclass (DKD, HC, IgAN, vasculitis) classifications. This pipeline was compared with the current state-of-the-art single-aetiology CKD urinary peptide models.RESULTS: In an independent test set, the developed models achieved 90.35% and 70.13% overall predictive accuracies, respectively, for the binary and the multiclass classifications. Omitting the UMAP step led to improved predictive accuracies (96.14% and 85.06%, respectively). As expected, the HC class was distinguished with the highest accuracy. The different classes displayed a tendency to form distinct clusters in the 3D space based on their disease state.CONCLUSION: Urinary peptide data present an effective basis for CKD aetiology differentiation using machine learning models. Although adding the UMAP step to the models did not improve prediction accuracy, it may provide a unique visualization advantage. Additional studies are warranted to further validate the pipeline's clinical potential as well as to expand it to other CKD aetiologies and also other diseases.

U2 - 10.1093/ndt/gfad200

DO - 10.1093/ndt/gfad200

M3 - SCORING: Journal article

C2 - 37697716

VL - 39

SP - 453

EP - 462

JO - NEPHROL DIAL TRANSPL

JF - NEPHROL DIAL TRANSPL

SN - 0931-0509

IS - 3

ER -