Metabolomic Biomarkers in Blood Samples Identify Cancers in a Mixed Population of Patients with Nonspecific Symptoms

Larkin, James R.; Anthony, Suzie; Johanssen, Vanessa A.; Yeo, Tianrong; Sealey, Megan; Yates, Abi G.; Smith, Claire Friedemann; Claridge, Timothy D. W.; Nicholson, Brian D; Moreland, Julie-Ann; Gleeson, Fergus; Sibson, Nicola R.; Anthony, Daniel C.; Probert, Fay

doi:10.1158/1078-0432.ccr-21-2855

Cited by 37 publications

(26 citation statements)

References 47 publications

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“…One of the hallmarks of cancer is metabolic reprogramming 8 . Differences in metabolite and protein abundancies in peripheral blood are used as biomarkers and can reveal patients harboring a malignancy 5,6,9,10 , detect upregulation of alternative energy consumption or inflammatory responses associated with cancer 5,9,10 . Here, we report a difference in plasma metabolite patterns between UM-patients and control-participants (Figure 1) and annotated, metabolites in UM-patients putatively associated with malignant processes (eFigure 8).…”

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

“…Blood-based biomarkers have the potential to replace invasive characterization, but tumor biomarker abundance in blood of UM-patients is often low 4 . Untargeted metabolomics allows for hypothesis-free biomarker detection and plasma metabolome studies show promising results in the detection of different types of cancer 5,6 . We investigated whether differences in metabolite patterns could distinguish UM-patients from control-participants and if we could identify prognostically relevant UM-patient subgroups.…”

Section: Introductionmentioning

confidence: 99%

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Blood Plasma Metabolomics to Support Uveal Melanoma Diagnosis

Bruyn

Bongaerts²,

Bonte³

et al. 2022

Preprint

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ImportanceUveal Melanomas (UM) micro-metastasis can be present prior to diagnosis and relapse after treatment. Earlier detection resulted in an increased incidence of small (T1 and T2) tumors allowing for novel eye-preserving treatment strategies but reducing available tumor tissue needed for prognostic genomic profiling, creating the need for minimal-invasive detection and novel prognostication methods.ObjectiveTo determine whether tumor presence can be confirmed using metabolite patterns in blood plasma and to evaluate if these patterns differ between high risk (BRCA1-associated protein-1, BAP1), intermediate risk (Splicing Factor 3b Subunit 1, SF3B1) and low risk (Eukaryotic Translation Initiation Factor 1A X-Linked, EIF1AX) mutated tumors.DesignRetrospective observational study including discovery (n=53) and replication (n=42) convenience sample sets compared to unaffected control-participants (n=46) as well as across mutation-based subgroups.SettingPatients from two tertiary referral centers specialized in ocular oncology: The Rotterdam Eye Hospital and the Erasmus MC Cancer Institute were included.ParticipantsSex-matched controls and patients were included based on their prognostic relevant secondary driver mutations. Peripheral blood plasma was collected at diagnosis, prior to treatment. Exclusion criteria were the presence of other malignancies or co-occurrence of systemic diseases at time of diagnosis.Main outcome and measureMetabolite profiles of patients and control-participants were generated as mass/charge (m/z) features using ultra-high performance liquid chromatography mass-spectrometry. After normalization, discriminatory feature patterns were determined using a random forest classifier and leave-one-out cross-validation.ResultsWe detected differential metabolic patterns with a sensitivity of 0.95 and 0.90 and a specificity of 0.98 and 0.98 in the positive and negative ion modes, respectively. The accuracy of the model for classifying the subgroups was insufficient for the discovery (0.600 and 0.614 in the positive and negative ion modes, respectively) and replication cohort (0.544 and 0.672 in the positive and negative ion modes, respectively).Conclusion and relevanceMinimally invasive metabolomics does not discriminate between the prognostic relevant BAP1, SF3B1 and EIF1AX mutated UM-subgroups. However, this technique has the potential to allow for minimal invasive screening as it distinguishes metabolite patterns in peripheral blood derived plasma of UM-patients from control-participants.Key pointsQuestionCan we discriminate uveal melanoma patients and mutation subgroups from unaffected control-participants using the metabolome of peripheral blood plasma taken at time of diagnosis?FindingsIn this retrospective observational study, we find a low sensitivity and specificity to detect subgroups but a high sensitivity and specificity to discriminate patients from control-participants by measuring metabolite abundancy in plasma using ultra-high performance liquid chromatography mass-spectrometry and reach a receiver operating characteristic area under the curve of 0.993.MeaningThese results suggest that surveying the metabolome of uveal melanoma patients could aid in the minimal invasive detection of uveal melanoma.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Blood Plasma Metabolomics to Support Uveal Melanoma Diagnosis

Bruyn

Bongaerts²,

Bonte³

et al. 2022

Preprint

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“…[22] Differences in metabolite abundancies in peripheral blood are used as biomarkers and can reveal patients harboring a malignancy, detect upregulation of alternative energy consumption or in ammatory responses associated with cancer. [10,12,23,24] Furthermore, recent studies describe the potential of plasma derived metabolomics for early detection of malignancies. [10,25] To date, these differences in plasma derived metabolite abundancies have not been reported in UM-patients.…”

Section: Discussionmentioning

confidence: 99%

“…Dysregulation of speci c metabolic pathways is associated to malignant processes [9] and these altered metabolic pathways are detected in blood of patients harboring varying malignancies, such as lung adenocarcinoma [10] and colorectal cancer [11]. Untargeted metabolomics allows for hypothesis-free biomarker detection and plasma metabolome studies show promising results in the early detection of different types of cancer [10,12]. We hypothesized that differences in metabolite patterns could distinguish UM-patients from control-participants and that metabolic phenotypes could distinguish prognostically relevant UM-patient subgroups.…”

Section: Introductionmentioning

confidence: 99%

Minimally invasive metabolomics reveals a distinct uveal melanoma metabolic phenotype

Bruyn

Bongaerts

Bonte

et al. 2022

Preprint

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Background Uveal Melanoma (UM) micro-metastases can be present prior to diagnosis and relapse after treatment. Earlier detection resulted in an increased incidence of small (T1 and T2) tumors allowing for novel eye-preserving treatment strategies, but reducing available tumor tissue needed for prognostic genomic profiling. Thus, creating the need for minimal-invasive detection and novel prognostication methods. We determined whether tumor presence can be confirmed using metabolite patterns in blood plasma and evaluated if these patterns differ between high risk (BRCA1-associated protein-1, BAP1), intermediate risk (Splicing Factor 3b Subunit 1, SF3B1) and low risk (Eukaryotic Translation Initiation Factor 1A X-Linked, EIF1AX) mutated tumors. Methods In this retrospective observational study, samples of UM-patients in a discovery (n = 53) and replication (n = 42) set were compared to unaffected control-participants (n = 46) as well as across mutation-based subgroups. Peripheral blood plasma was collected prior to treatment. Metabolite profiles of patients and control-participants were generated as mass/charge (m/z) features using ultra-high performance liquid chromatography mass-spectrometry. After normalization, discriminatory feature patterns were determined using a random forest classifier and a leave-one-out cross-validation procedure. Results We detected differential metabolic patterns between UM-patients and control-participants with a sensitivity of 0.95 and 0.90 and a specificity of 0.98 and 0.98 in the positive and negative ion modes, respectively. Overall, the performance of the model for classifying the subgroups was insufficient in both the positive (merged dataset F1 scores: BAP1: 0.64, SF3B1: 0.37, and EIF1AX: 0.35) and negative (merged dataset F1 scores: BAP1: 0.60, SF3B1: 0.32, and EIF1AX: 0.36) ion modes, respectively. Pathway analysis using annotated metabolites indicated upregulation of tRNA charging, and glycine usage for the creatine biosynthesis. Purine ribonucleosides degradation and the super pathway of citrulline metabolism were downregulated in UM-patients. An increased salvage of bases or decreased purine degradation could indicate a higher energy consumption. Conclusion Minimally-invasive metabolomics has the potential to allow for minimally invasive screening as it distinguishes metabolite patterns, that are putatively associated with oncogenic processes, in peripheral blood derived plasma of UM-patients from control-participants at the time of diagnosis.

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Metabolomics in oncology

et al. 2023

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Background: Oncogenic transformation alters intracellular metabolism and contributes to the growth of malignant cells. Metabolomics, or the study of small molecules, can reveal insight about cancer progression that other biomarker studies cannot.Number of metabolites involved in this process have been in spotlight for cancer detection, monitoring, and therapy.Recent Findings: In this review, the "Metabolomics" is defined in terms of current technology having both clinical and translational applications. Researchers have shown metabolomics can be used to discern metabolic indicators non-invasively using different analytical methods like positron emission tomography, magnetic resonance spectroscopic imaging etc. Metabolomic profiling is a powerful and technically feasible way to track changes in tumor metabolism and gauge treatment response across time. Recent studies have shown metabolomics can also predict individual metabolic changes in response to cancer treatment, measure medication efficacy, and monitor drug resistance. Its significance in cancer development and treatment is summarized in this review. Conclusion:Although in infancy, metabolomics can be used to identify treatment options and/or predict responsiveness to cancer treatments. Technical challenges like database management, cost and methodical knowhow still persist. Overcoming these challenges in near further can help in designing new treatment régimes with increased sensitivity and specificity.

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Metabolomic Biomarkers in Blood Samples Identify Cancers in a Mixed Population of Patients with Nonspecific Symptoms

Cited by 37 publications

References 47 publications

Blood Plasma Metabolomics to Support Uveal Melanoma Diagnosis

Blood Plasma Metabolomics to Support Uveal Melanoma Diagnosis

Minimally invasive metabolomics reveals a distinct uveal melanoma metabolic phenotype

Metabolomics in oncology

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