Sequential and Hybrid PET/MRI Acquisition in Follow-Up Examination of Glioblastoma Show Similar Diagnostic Performance

Julian Ziegenfeuter; Claire Delbridge; Denise Bernhardt; Jens Gempt; Friederike Schmidt-Graf; Michael Griessmair; Marie Thomas; Hanno S Meyer; Claus Zimmer; Bernhard Meyer; Stephanie E Combs; Igor Yakushev; Benedikt Wiestler; Marie-Christin Metz

doi:10.3390/cancers15010083

Sequential and Hybrid PET/MRI Acquisition in Follow-Up Examination of Glioblastoma Show Similar Diagnostic Performance

Standard

Sequential and Hybrid PET/MRI Acquisition in Follow-Up Examination of Glioblastoma Show Similar Diagnostic Performance. / Ziegenfeuter, Julian; Delbridge, Claire; Bernhardt, Denise; Gempt, Jens; Schmidt-Graf, Friederike; Griessmair, Michael; Thomas, Marie; Meyer, Hanno S; Zimmer, Claus; Meyer, Bernhard; Combs, Stephanie E; Yakushev, Igor; Wiestler, Benedikt; Metz, Marie-Christin.

in: CANCERS, Jahrgang 15, Nr. 1, 83, 23.12.2022.

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

Harvard

Ziegenfeuter, J, Delbridge, C, Bernhardt, D, Gempt, J, Schmidt-Graf, F, Griessmair, M, Thomas, M, Meyer, HS, Zimmer, C, Meyer, B, Combs, SE, Yakushev, I, Wiestler, B & Metz, M-C 2022, 'Sequential and Hybrid PET/MRI Acquisition in Follow-Up Examination of Glioblastoma Show Similar Diagnostic Performance', CANCERS, Jg. 15, Nr. 1, 83. https://doi.org/10.3390/cancers15010083

APA

Ziegenfeuter, J., Delbridge, C., Bernhardt, D., Gempt, J., Schmidt-Graf, F., Griessmair, M., Thomas, M., Meyer, H. S., Zimmer, C., Meyer, B., Combs, S. E., Yakushev, I., Wiestler, B., & Metz, M-C. (2022). Sequential and Hybrid PET/MRI Acquisition in Follow-Up Examination of Glioblastoma Show Similar Diagnostic Performance. CANCERS, 15(1), [83]. https://doi.org/10.3390/cancers15010083

Vancouver

Ziegenfeuter J, Delbridge C, Bernhardt D, Gempt J, Schmidt-Graf F, Griessmair M et al. Sequential and Hybrid PET/MRI Acquisition in Follow-Up Examination of Glioblastoma Show Similar Diagnostic Performance. CANCERS. 2022 Dez 23;15(1). 83. https://doi.org/10.3390/cancers15010083

Bibtex

@article{fedb970b011042929d24c63524ddf696,

title = "Sequential and Hybrid PET/MRI Acquisition in Follow-Up Examination of Glioblastoma Show Similar Diagnostic Performance",

abstract = "Both positron emission tomography (PET) and magnetic resonance imaging (MRI), including dynamic susceptibility contrast perfusion (DSC-PWI), are crucial for treatment monitoring of patients with high-grade gliomas. In clinical practice, they are usually conducted at separate time points. Whether this affects their diagnostic performance is presently unclear. To this end, we retrospectively reviewed 38 patients with pathologically confirmed glioblastoma (IDH wild-type) and suspected tumor recurrence after radiotherapy. Only patients who received both a PET−MRI (where DSC perfusion was acquired simultaneously with a FET-PET) and a separate MRI exam (including DSC perfusion) were included. Tumors were automatically segmented into contrast-enhancing tumor (CET), necrosis, and edema. To compare the simultaneous as well as the sequential DSC perfusion to the FET-PET, we calculated Dice overlap, global mutual information as well as voxel-wise Spearman correlation of hotspot areas. For the joint assessment of PET and MRI, we computed logistic regression models for the differentiation between true progression (PD) and treatment-related changes (TRC) using simultaneously or sequentially acquired images as input data. We observed no significant differences between Dice overlap (p = 0.17; paired t-test), mutual information (p = 0.18; paired t-test) and Spearman correlation (p = 0.90; paired t-test) when comparing simultaneous PET−MRI and sequential PET/MRI acquisition. This also held true for the subgroup of patients with >14 days between exams. Importantly, for the diagnostic performance, ROC analysis showed similar AUCs for differentiation of PD and TRC (AUC simultaneous PET: 0.77; AUC sequential PET: 0.78; p = 0.83, DeLong{\textquoteright}s test). We found no relevant differences between simultaneous and sequential acquisition of FET-PET and DSC perfusion, also regarding their diagnostic performance. Given the increasing attention to multi-parametric assessment of glioma treatment response, our results reassuringly suggest that sequential acquisition is clinically and scientifically acceptable.",

author = "Julian Ziegenfeuter and Claire Delbridge and Denise Bernhardt and Jens Gempt and Friederike Schmidt-Graf and Michael Griessmair and Marie Thomas and Meyer, {Hanno S} and Claus Zimmer and Bernhard Meyer and Combs, {Stephanie E} and Igor Yakushev and Benedikt Wiestler and Marie-Christin Metz",

year = "2022",

month = dec,

day = "23",

doi = "10.3390/cancers15010083",

language = "English",

volume = "15",

journal = "CANCERS",

issn = "2072-6694",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "1",

}

RIS

TY - JOUR

T1 - Sequential and Hybrid PET/MRI Acquisition in Follow-Up Examination of Glioblastoma Show Similar Diagnostic Performance

AU - Ziegenfeuter, Julian

AU - Delbridge, Claire

AU - Bernhardt, Denise

AU - Gempt, Jens

AU - Schmidt-Graf, Friederike

AU - Griessmair, Michael

AU - Thomas, Marie

AU - Meyer, Hanno S

AU - Zimmer, Claus

AU - Meyer, Bernhard

AU - Combs, Stephanie E

AU - Yakushev, Igor

AU - Wiestler, Benedikt

AU - Metz, Marie-Christin

PY - 2022/12/23

Y1 - 2022/12/23

N2 - Both positron emission tomography (PET) and magnetic resonance imaging (MRI), including dynamic susceptibility contrast perfusion (DSC-PWI), are crucial for treatment monitoring of patients with high-grade gliomas. In clinical practice, they are usually conducted at separate time points. Whether this affects their diagnostic performance is presently unclear. To this end, we retrospectively reviewed 38 patients with pathologically confirmed glioblastoma (IDH wild-type) and suspected tumor recurrence after radiotherapy. Only patients who received both a PET−MRI (where DSC perfusion was acquired simultaneously with a FET-PET) and a separate MRI exam (including DSC perfusion) were included. Tumors were automatically segmented into contrast-enhancing tumor (CET), necrosis, and edema. To compare the simultaneous as well as the sequential DSC perfusion to the FET-PET, we calculated Dice overlap, global mutual information as well as voxel-wise Spearman correlation of hotspot areas. For the joint assessment of PET and MRI, we computed logistic regression models for the differentiation between true progression (PD) and treatment-related changes (TRC) using simultaneously or sequentially acquired images as input data. We observed no significant differences between Dice overlap (p = 0.17; paired t-test), mutual information (p = 0.18; paired t-test) and Spearman correlation (p = 0.90; paired t-test) when comparing simultaneous PET−MRI and sequential PET/MRI acquisition. This also held true for the subgroup of patients with >14 days between exams. Importantly, for the diagnostic performance, ROC analysis showed similar AUCs for differentiation of PD and TRC (AUC simultaneous PET: 0.77; AUC sequential PET: 0.78; p = 0.83, DeLong’s test). We found no relevant differences between simultaneous and sequential acquisition of FET-PET and DSC perfusion, also regarding their diagnostic performance. Given the increasing attention to multi-parametric assessment of glioma treatment response, our results reassuringly suggest that sequential acquisition is clinically and scientifically acceptable.

AB - Both positron emission tomography (PET) and magnetic resonance imaging (MRI), including dynamic susceptibility contrast perfusion (DSC-PWI), are crucial for treatment monitoring of patients with high-grade gliomas. In clinical practice, they are usually conducted at separate time points. Whether this affects their diagnostic performance is presently unclear. To this end, we retrospectively reviewed 38 patients with pathologically confirmed glioblastoma (IDH wild-type) and suspected tumor recurrence after radiotherapy. Only patients who received both a PET−MRI (where DSC perfusion was acquired simultaneously with a FET-PET) and a separate MRI exam (including DSC perfusion) were included. Tumors were automatically segmented into contrast-enhancing tumor (CET), necrosis, and edema. To compare the simultaneous as well as the sequential DSC perfusion to the FET-PET, we calculated Dice overlap, global mutual information as well as voxel-wise Spearman correlation of hotspot areas. For the joint assessment of PET and MRI, we computed logistic regression models for the differentiation between true progression (PD) and treatment-related changes (TRC) using simultaneously or sequentially acquired images as input data. We observed no significant differences between Dice overlap (p = 0.17; paired t-test), mutual information (p = 0.18; paired t-test) and Spearman correlation (p = 0.90; paired t-test) when comparing simultaneous PET−MRI and sequential PET/MRI acquisition. This also held true for the subgroup of patients with >14 days between exams. Importantly, for the diagnostic performance, ROC analysis showed similar AUCs for differentiation of PD and TRC (AUC simultaneous PET: 0.77; AUC sequential PET: 0.78; p = 0.83, DeLong’s test). We found no relevant differences between simultaneous and sequential acquisition of FET-PET and DSC perfusion, also regarding their diagnostic performance. Given the increasing attention to multi-parametric assessment of glioma treatment response, our results reassuringly suggest that sequential acquisition is clinically and scientifically acceptable.

U2 - 10.3390/cancers15010083

DO - 10.3390/cancers15010083

M3 - SCORING: Journal article

C2 - 36612079

VL - 15

JO - CANCERS

JF - CANCERS

SN - 2072-6694

IS - 1

M1 - 83

ER -