Initial Global Post Market Experience with PIQE

Erin Kelly, Ph.D.
Strategic Clinical Scientist
CT-MR Solution Planning Department
Canon Medical Systems Corporation
Shelton Caruthers, Ph.D.
Senior Strategic Manager, Global Clinical Validation and Collaboration
CT-MR Solution Planning Department
Canon Medical Systems Corporation
To the clinical MRI community, Precise IQ Engine (PIQE) offers the ability to generate images with higher in-plane matrix sizes from lower resolution images, often making this possible even at a faster acquisition time. Based on the advanced scientific principles of deep learning-based denoising and an image up-sampling process, PIQE can triple the in-plane acquired matrix size in both directions, producing higher image sharpness. With PIQE, valuable SNR is not traded for resolution but preserved and even enhanced due to denoising. More technical details explaining how PIQE works can be accessed by clicking the following link. Additionally, related articles including the validation process can be accessed in the "More Information" section at the bottom of this page.

Learn how PIQE works

As an integral component of the product release process and overall life cycle, it is especially important to monitor clinical adoption of new and innovative applications at the earliest stage. In partnership with the Johns Hopkins University (JHU) School of Medicine in Baltimore, Maryland, USA, and the Diagnostic Imaging Unit at Clinica Creu Blanca, Barcelona, Spain, Canon Medical Systems has provided the unique opportunity to evaluate product implementation immediately after initial release to the market. This provides an opportunity to confirm the outcomes of prior validation studies as well as expand our knowledge of clinical benefits and potential limitations. Both aspects are useful in building upon education, training and enabling a more seamless clinical adoption.

During this early post market implementation of PIQE, strategies involved the acquisition and multiple reconstructions of repeated scans with low and high acquisition matrices compared to the standard clinical protocol. At JHU, investigators sought to determine the lower limit on the acquired matrix size which could be reconstructed to produce a high-quality, high-resolution image with PIQE. Similarly, Crue Blanca compared their standard, already high-quality clinical protocols to an ultra-high-resolution acquisition and a faster acquisition acquired at a lower resolution and reconstructed to the same ultra-high resolution. Sample comparisons of image quality, resolutions and acquisition times are shown in Figures 1 - 5.
Figure 1. Coronal T2-weighted images acquired on a 1.5T scanner (Vantage Orian). The faster acquisition + PIQE (panel C2) acquisition achieved a higher reconstructed pixel resolution in half the acquisition time than the original standard protocol (panel A1) with equivalent structural detail and image quality. Furthermore, the faster PIQE (panel C2) reconstruction achieved a similar pixel spacing to the natively-acquired high resolution acquisition and a faster acquisition time compared to the high resolution image acquisition (panel B1), with a reduced appearance of noise.
Standard (A1) Standard PIQE (A2) High Resolution (B1) High Resolution PIQE (B2) Faster (C1) Faster PIQE (C2)
Acquired Matrix 224x224 224x224 352x352 352x352 192x192 192x192
Field of View (mm) 150 150 170 170 150 150
Slice Thickness (mm) 2 2 2.2 2.2 2 2
Scan Time 2 min 12 sec 2 min 12 sec 2 min 25 sec 2 min 25 sec 1 min 5 sec 1 min 5 sec
Reconstructed Matrix 448x448 672x672 704x704 1056x1056 384x384 576x576
Pixel spacing (mm) 0.33 0.22 0.24 0.16 0.39 0.26
Figure 2. Sagittal PD Fat Saturation-weighted images of an ankle acquired on a 1.5T scanner (Vantage Orian). The Faster PIQE (C2) acquisition achieved a higher reconstructed pixel resolution in half the acquisition time compared to the original standard protocol (A1) with equivalent structural detail and image quality. Furthermore, the faster PIQE (panel C2) reconstruction achieved the same pixel spacing to the natively-acquired high resolution acquisition in 1/3 of the acquisition time compared to the high resolution image acquisition (panel B1), with a reduced appearance of noise.
Standard (A1) Standard PIQE (A2) High Resolution (B1) High Resolution PIQE (B2) Faster (C1) Faster PIQE (C2)
Acquired Matrix 256x256 256x256 256x288 256x288 192x192 192x192
Field of View (mm) 130 130 130 130 130 130
Slice Thickness (mm) 3 3 1.8 1.8 3 3
Scan Time 1 min 55 sec 1 min 55 sec 3 min 4 sec 3 min 4 sec 56 sec 56 sec
Reconstructed Matrix 512x512 768x768 576x576 864x864 384x384 576x576
Pixel spacing (mm) 0.25 0.17 0.23 0.15 0.34 0.23
Figure 3. Axial PD Fat Saturation-weighted images of a knee acquired on a 1.5T scanner (Vantage Orian). The Faster PIQE (panel C2) acquisition achieved a higher reconstructed pixel spacing in less than half the acquisition time than the original standard protocol (panel A1) with the appearance of improved structural detail and image quality. Furthermore, the faster PIQE (panel C2) reconstruction achieved a similar pixel spacing to the natively-acquired high resolution acquisition in 1/3 of the acquisition time compared to the high resolution image acquisition (panel B1) and similar structural detail.
Standard (A1) Standard PIQE (A2) High Resolution (B1) High Resolution PIQE (B2) Faster (C1) Faster PIQE (C2)
Acquired Matrix 256x256 256x256 352x288 352x288 192x192 192x192
Field of View (mm) 160 160 160 160 160 160
Slice Thickness (mm) 2.5 2.5 2.2 2.2 2.5 2.5
Scan Time 2 min 11 sec 2 min 11 sec 3 min 19 sec 3 min 19 sec 56 sec 56 sec
Reconstructed Matrix 512x512 768x768 704x704 1056x1056 384x384 576x576
Pixel spacing (mm) 0.31 0.21 0.23 0.15 0.42 0.28
Figure 4. T1-Inversion Recovery -weighted images of a brain acquired on a 3T scanner (Vantage Galan 3T). The Fast PIQE (B2) acquisition achieved the same reconstructed pixel spacing in half the acquisition time than the original standard protocol with similar image quality and reduced noise. Furthermore, the faster/ thinner slice PIQE (panel C2) reconstruction reduced the slice thickness by half, enabling finer reconstruction in the slice direction with similar scan time and high image quality.
Standard (A1) Standard PIQE (A2) Faster (B1) Faster PIQE (B2) Fast/Thin Slice (C1) Fast/Thin Slice PIQE (C2)
Acquired Matrix 288x288 288x288 192x192 192x192 192x192 192x192
Field of View (mm) 230 230 230 230 230 230
Slice Thickness (mm) 4 4 4 4 2 2
Scan Time 2 min 44 sec 2 min 44 sec 1 min 18 sec 1 min 18 sec 2 min 36 sec 2 min 36 sec
Reconstructed Matrix 576x576 864x864 384x384 576x576 384x384 576x576
Pixel spacing (mm) 0.4 0.27 0.6 0.4 0.6 0.4
Figure 5: Sagittal T2-weighted images of a cervical spine acquired on a 3T scanner (Vantage Galan 3T). This example shows how the time saved by reducing the acquisition matrix can be spent on acquiring additional slices to cover the region of interest with finer resolution in the slice direction.
Standard (A1) Standard PIQE (A2) Fast/Thin Slice (B1) Fast/Thin Slice PIQE (B2)
Acquired Matrix 288x288 288x288 192x192 192x192
Field of View (mm) 200 200 200 200
Slice Thickness (mm) 3 3 2 2
Scan Time 2 min 29 sec 2 min 29 sec 2 min 39 sec 2 min 39 sec
Reconstructed Matrix 576x576 864x864 384x384 576x576
Pixel spacing (mm) 0.35 0.23 0.52 0.35
In summary, these initial experiences with PIQE on Vantage Orian (1.5T) and Vantage Galan 3T scanners have begun to showcase the unique value PIQE offers in overcoming MRI specific challenges. The traditional challenge of consistently and reliably achieving high image quality in a shortened acquisition time is no longer a big hurdle in MRI. Reconstruction with PIQE enables shortened acquisition times by lowering the acquired pixel resolution, while deep learning and up-sampling allows for the reconstruction of superior high-resolution images, preserving structural detail and removing the noise. PIQE can be utilized differently in a variety of clinical scenarios. When faster scan times are needed to improve patient comfort or when higher resolution images and/or additional thinner slices are needed to visualize super fine detailed structures, PIQE can offer a solution.

Disclaimer
Some features presented in this article may not be commercially available on all systems shown or may require the purchase of additional options. Due to local regulatory processes, some commercial features included in this publication may not be available in some countries. Please contact your local representative from Canon Medical Systems for details and the most current information.

Deep Learning technology is used in the design stage of the image reconstruction processing. The system itself does not have self-learning capabilities. The contents of this report include the personal opinions of the authors based on their clinical experience and knowledge.

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