Deep learning approximation of attenuation maps for myocardial perfusion SPECT with an IQ⋅SPECT collimator
Huxohl T, Patel G, Zabel R, Burchert W (2023)
EJNMMI Physics 10(1): 49.
Zeitschriftenaufsatz
| Veröffentlicht | Englisch
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Autor*in
Huxohl, TaminoUniBi 
;
Patel, Gopesh;
Zabel, Reinhard;
Burchert, Wolfgang
;
Patel, Gopesh;
Zabel, Reinhard;
Burchert, WolfgangEinrichtung
Abstract / Bemerkung
**Background**
The use of CT images for attenuation correction of myocardial perfusion imaging with single photon emission computer tomography (SPECT) increases diagnostic confidence. However, acquiring a CT image registered to a SPECT image is often not possible because most scanners are SPECT-only. It is possible to approximate attenuation maps using deep learning, but this has not yet been shown to work for a SPECT scanner with an IQ⋅SPECT collimator. This study investigates whether it is possible to approximate attenuation maps from non-attenuation-corrected (nAC) reconstructions acquired with a SPECT scanner equipped with an IQ⋅SPECT collimator.
**Methods**
Attenuation maps and reconstructions were acquired retrospectively for 150 studies. A U–Net was trained to predict attenuation maps from nAC reconstructions using the conditional generative adversarial network framework. Predicted attenuation maps are compared to real attenuation maps using the normalized mean absolute error (NMAE). Attenuation-corrected reconstructions were computed, and the resulting polar maps were compared by pixel and by average perfusion per segment using the absolute percent error (APE). The training and evaluation code is available at https://gitlab.ub.uni-bielefeld.de/thuxohl/mu-map.
**Results**
Predicted attenuation maps are similar to real attenuation maps, achieving an NMAE of 0.020±0.007. The same is true for polar maps generated from reconstructions with predicted attenuation maps compared to CT-based attenuation maps. Their pixel-wise absolute distance is 3.095±3.199, and the segment-wise APE is 1.155±0.769.
**Conclusions** It is feasible to approximate attenuation maps from nAC reconstructions acquired by a scanner with an IQ⋅SPECT collimator using deep learning.
The use of CT images for attenuation correction of myocardial perfusion imaging with single photon emission computer tomography (SPECT) increases diagnostic confidence. However, acquiring a CT image registered to a SPECT image is often not possible because most scanners are SPECT-only. It is possible to approximate attenuation maps using deep learning, but this has not yet been shown to work for a SPECT scanner with an IQ⋅SPECT collimator. This study investigates whether it is possible to approximate attenuation maps from non-attenuation-corrected (nAC) reconstructions acquired with a SPECT scanner equipped with an IQ⋅SPECT collimator.
**Methods**
Attenuation maps and reconstructions were acquired retrospectively for 150 studies. A U–Net was trained to predict attenuation maps from nAC reconstructions using the conditional generative adversarial network framework. Predicted attenuation maps are compared to real attenuation maps using the normalized mean absolute error (NMAE). Attenuation-corrected reconstructions were computed, and the resulting polar maps were compared by pixel and by average perfusion per segment using the absolute percent error (APE). The training and evaluation code is available at https://gitlab.ub.uni-bielefeld.de/thuxohl/mu-map.
**Results**
Predicted attenuation maps are similar to real attenuation maps, achieving an NMAE of 0.020±0.007. The same is true for polar maps generated from reconstructions with predicted attenuation maps compared to CT-based attenuation maps. Their pixel-wise absolute distance is 3.095±3.199, and the segment-wise APE is 1.155±0.769.
**Conclusions** It is feasible to approximate attenuation maps from nAC reconstructions acquired by a scanner with an IQ⋅SPECT collimator using deep learning.
Erscheinungsjahr
2023
Zeitschriftentitel
EJNMMI Physics
Band
10
Ausgabe
1
Art.-Nr.
49
Urheberrecht / Lizenzen
eISSN
2197-7364
Page URI
https://pub.uni-bielefeld.de/record/2983253
Zitieren
Huxohl T, Patel G, Zabel R, Burchert W. Deep learning approximation of attenuation maps for myocardial perfusion SPECT with an IQ⋅SPECT collimator. EJNMMI Physics. 2023;10(1): 49.
Huxohl, T., Patel, G., Zabel, R., & Burchert, W. (2023). Deep learning approximation of attenuation maps for myocardial perfusion SPECT with an IQ⋅SPECT collimator. EJNMMI Physics, 10(1), 49. https://doi.org/10.1186/s40658-023-00568-1
Huxohl, Tamino, Patel, Gopesh, Zabel, Reinhard, and Burchert, Wolfgang. 2023. “Deep learning approximation of attenuation maps for myocardial perfusion SPECT with an IQ⋅SPECT collimator”. EJNMMI Physics 10 (1): 49.
Huxohl, T., Patel, G., Zabel, R., and Burchert, W. (2023). Deep learning approximation of attenuation maps for myocardial perfusion SPECT with an IQ⋅SPECT collimator. EJNMMI Physics 10:49.
Huxohl, T., et al., 2023. Deep learning approximation of attenuation maps for myocardial perfusion SPECT with an IQ⋅SPECT collimator. EJNMMI Physics, 10(1): 49.
T. Huxohl, et al., “Deep learning approximation of attenuation maps for myocardial perfusion SPECT with an IQ⋅SPECT collimator”, EJNMMI Physics, vol. 10, 2023, : 49.
Huxohl, T., Patel, G., Zabel, R., Burchert, W.: Deep learning approximation of attenuation maps for myocardial perfusion SPECT with an IQ⋅SPECT collimator. EJNMMI Physics. 10, : 49 (2023).
Huxohl, Tamino, Patel, Gopesh, Zabel, Reinhard, and Burchert, Wolfgang. “Deep learning approximation of attenuation maps for myocardial perfusion SPECT with an IQ⋅SPECT collimator”. EJNMMI Physics 10.1 (2023): 49.
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