Characterization of attenuation and respiratory motion artifacts and their influence on SPECT MP image evaluation using a dynamic phantom assembly with variable cardiac defects

Isabelle Chrysanthou-Baustert; Irene Polycarpou; Ourania Demetriadou; Lefteris Livieratos; Antonis Lontos; Antonis Antoniou; Stelios Christofides; Charalambos Yiannakkaras; Demetris Kaolis; Christoforos Panagidis; Paul K Marsden; Yiannis Parpottas

doi:10.1007/s12350-015-0378-y

Characterization of attenuation and respiratory motion artifacts and their influence on SPECT MP image evaluation using a dynamic phantom assembly with variable cardiac defects

Isabelle Chrysanthou-Baustert, Irene Polycarpou, Ourania Demetriadou, Lefteris Livieratos, Antonis Lontos, Antonis Antoniou, Stelios Christofides, Charalambos Yiannakkaras, Demetris Kaolis, Christoforos Panagidis, Paul K Marsden, Yiannis Parpottas

Research output: Contribution to journal › Article › peer-review

13 Citations (Scopus)

Abstract

BACKGROUND: A phantom assembly that simulates the respiratory motion of the heart was used to investigate artifacts and their impact on defect detection.

METHODS: SPECT/CT images were acquired for phantoms with and without small and large cardiac defects during normal and deep breathing, and also at four static respiratory phases. Acquisitions were reconstructed with and without AC, and with misalignment of transmission and emission scans. A quantitative analysis was performed to assess artifacts. Two physicians reported on defect presence or absence and their results were evaluated.

RESULTS: All large defects were correctly reported. Attenuation reduced uptake in the basal LV walls, increasing FN physicians' reports for small defects. Respiratory motion reduced uptake mainly in the anterior and inferior walls increasing FP and FN reports on images without and with small defects, respectively. Artifacts due to misalignment between CT and SPECT scans in normal breathing phantoms did not influence the physicians' reports.

CONCLUSIONS: Attenuation and respiratory motion correction should be applied to reduce artifacts before reporting on small defects in deep breathing conditions. Artifacts due to misalignment between CT and SPECT scans do not affect defect detection in normal breathing when the LV is co-registered in SPECT and CT images prior to AC.

Original language	English
Journal	Journal of Nuclear Cardiology
Early online date	4 Feb 2016
DOIs	https://doi.org/10.1007/s12350-015-0378-y
Publication status	E-pub ahead of print - 4 Feb 2016

Access to Document

10.1007/s12350-015-0378-y

Cite this

Chrysanthou-Baustert, I., Polycarpou, I., Demetriadou, O., Livieratos, L., Lontos, A., Antoniou, A., Christofides, S., Yiannakkaras, C., Kaolis, D., Panagidis, C., Marsden, P. K., & Parpottas, Y. (2016). Characterization of attenuation and respiratory motion artifacts and their influence on SPECT MP image evaluation using a dynamic phantom assembly with variable cardiac defects. Journal of Nuclear Cardiology. Advance online publication. https://doi.org/10.1007/s12350-015-0378-y

@article{cb5203cf404449cfbb97ffadf4437173,

title = "Characterization of attenuation and respiratory motion artifacts and their influence on SPECT MP image evaluation using a dynamic phantom assembly with variable cardiac defects",

abstract = "BACKGROUND: A phantom assembly that simulates the respiratory motion of the heart was used to investigate artifacts and their impact on defect detection.METHODS: SPECT/CT images were acquired for phantoms with and without small and large cardiac defects during normal and deep breathing, and also at four static respiratory phases. Acquisitions were reconstructed with and without AC, and with misalignment of transmission and emission scans. A quantitative analysis was performed to assess artifacts. Two physicians reported on defect presence or absence and their results were evaluated.RESULTS: All large defects were correctly reported. Attenuation reduced uptake in the basal LV walls, increasing FN physicians' reports for small defects. Respiratory motion reduced uptake mainly in the anterior and inferior walls increasing FP and FN reports on images without and with small defects, respectively. Artifacts due to misalignment between CT and SPECT scans in normal breathing phantoms did not influence the physicians' reports.CONCLUSIONS: Attenuation and respiratory motion correction should be applied to reduce artifacts before reporting on small defects in deep breathing conditions. Artifacts due to misalignment between CT and SPECT scans do not affect defect detection in normal breathing when the LV is co-registered in SPECT and CT images prior to AC.",

author = "Isabelle Chrysanthou-Baustert and Irene Polycarpou and Ourania Demetriadou and Lefteris Livieratos and Antonis Lontos and Antonis Antoniou and Stelios Christofides and Charalambos Yiannakkaras and Demetris Kaolis and Christoforos Panagidis and Marsden, {Paul K} and Yiannis Parpottas",

year = "2016",

month = feb,

day = "4",

doi = "10.1007/s12350-015-0378-y",

language = "English",

journal = "Journal of Nuclear Cardiology",

issn = "1071-3581",

publisher = "Springer New York",

}

Chrysanthou-Baustert, I, Polycarpou, I, Demetriadou, O, Livieratos, L, Lontos, A, Antoniou, A, Christofides, S, Yiannakkaras, C, Kaolis, D, Panagidis, C, Marsden, PK & Parpottas, Y 2016, 'Characterization of attenuation and respiratory motion artifacts and their influence on SPECT MP image evaluation using a dynamic phantom assembly with variable cardiac defects', Journal of Nuclear Cardiology. https://doi.org/10.1007/s12350-015-0378-y

Characterization of attenuation and respiratory motion artifacts and their influence on SPECT MP image evaluation using a dynamic phantom assembly with variable cardiac defects. / Chrysanthou-Baustert, Isabelle; Polycarpou, Irene; Demetriadou, Ourania et al.
In: Journal of Nuclear Cardiology, 04.02.2016.

Research output: Contribution to journal › Article › peer-review

TY - JOUR

T1 - Characterization of attenuation and respiratory motion artifacts and their influence on SPECT MP image evaluation using a dynamic phantom assembly with variable cardiac defects

AU - Chrysanthou-Baustert, Isabelle

AU - Polycarpou, Irene

AU - Demetriadou, Ourania

AU - Livieratos, Lefteris

AU - Lontos, Antonis

AU - Antoniou, Antonis

AU - Christofides, Stelios

AU - Yiannakkaras, Charalambos

AU - Kaolis, Demetris

AU - Panagidis, Christoforos

AU - Marsden, Paul K

AU - Parpottas, Yiannis

PY - 2016/2/4

Y1 - 2016/2/4

N2 - BACKGROUND: A phantom assembly that simulates the respiratory motion of the heart was used to investigate artifacts and their impact on defect detection.METHODS: SPECT/CT images were acquired for phantoms with and without small and large cardiac defects during normal and deep breathing, and also at four static respiratory phases. Acquisitions were reconstructed with and without AC, and with misalignment of transmission and emission scans. A quantitative analysis was performed to assess artifacts. Two physicians reported on defect presence or absence and their results were evaluated.RESULTS: All large defects were correctly reported. Attenuation reduced uptake in the basal LV walls, increasing FN physicians' reports for small defects. Respiratory motion reduced uptake mainly in the anterior and inferior walls increasing FP and FN reports on images without and with small defects, respectively. Artifacts due to misalignment between CT and SPECT scans in normal breathing phantoms did not influence the physicians' reports.CONCLUSIONS: Attenuation and respiratory motion correction should be applied to reduce artifacts before reporting on small defects in deep breathing conditions. Artifacts due to misalignment between CT and SPECT scans do not affect defect detection in normal breathing when the LV is co-registered in SPECT and CT images prior to AC.

AB - BACKGROUND: A phantom assembly that simulates the respiratory motion of the heart was used to investigate artifacts and their impact on defect detection.METHODS: SPECT/CT images were acquired for phantoms with and without small and large cardiac defects during normal and deep breathing, and also at four static respiratory phases. Acquisitions were reconstructed with and without AC, and with misalignment of transmission and emission scans. A quantitative analysis was performed to assess artifacts. Two physicians reported on defect presence or absence and their results were evaluated.RESULTS: All large defects were correctly reported. Attenuation reduced uptake in the basal LV walls, increasing FN physicians' reports for small defects. Respiratory motion reduced uptake mainly in the anterior and inferior walls increasing FP and FN reports on images without and with small defects, respectively. Artifacts due to misalignment between CT and SPECT scans in normal breathing phantoms did not influence the physicians' reports.CONCLUSIONS: Attenuation and respiratory motion correction should be applied to reduce artifacts before reporting on small defects in deep breathing conditions. Artifacts due to misalignment between CT and SPECT scans do not affect defect detection in normal breathing when the LV is co-registered in SPECT and CT images prior to AC.

U2 - 10.1007/s12350-015-0378-y

DO - 10.1007/s12350-015-0378-y

M3 - Article

C2 - 26846369

SN - 1071-3581

JO - Journal of Nuclear Cardiology

JF - Journal of Nuclear Cardiology

ER -

Characterization of attenuation and respiratory motion artifacts and their influence on SPECT MP image evaluation using a dynamic phantom assembly with variable cardiac defects

Abstract

Access to Document

Fingerprint

Cite this