1 / 16

QIBA CT Volumetrics - Cross-Platform Study (Group 1C)

QIBA CT Volumetrics - Cross-Platform Study (Group 1C). September 2, 2009 Interclinical Comparison of CT Volumetry Quantitative Imaging Biomarker Alliance Dr. Charles Fenimore, NIST. Charge.

fernando
Download Presentation

QIBA CT Volumetrics - Cross-Platform Study (Group 1C)

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. QIBA CT Volumetrics - Cross-Platform Study (Group 1C) September 2, 2009 Interclinical Comparison of CT Volumetry Quantitative Imaging Biomarker Alliance Dr. Charles Fenimore, NIST

  2. Charge • To agree on the scanner settings and other protocol elements under which imagery is to be collected. • To agree on requirements of phantoms to be imaged/measured. • To agree on the platforms and centers to be selected for imagery collection. • To agree on the site(s) and methods for the reader study. • To identify the measurements and the algorithms for use in image processing. • To specify the analysis of the measurements.

  3. Goals Measure the volume of nodules on CT imagery collected from several CT scanners and sites. Protocol is to be defined in relation to QIBA Vol CT 2 specifications. Protocol is to include a branch specifying performance. Measure image noise and other image quality factors and determine their impact on the measurement of volume. Analyze the accuracy and precision of volume measurements for all design factors including: site, device, scanner settings, & reader/algorithm/software. Determine the minimum detectable level of change that can be achieved when measuring nodules in phantom datasets.

  4. Goals 1 and 2 Measure the volume of nodules on CT imagery collected from several CT scanners and sites, etc. Measure “image noise” and determine its impact on the measurement of volume, to facilitate scanner comparison. Realization of these goals is discussed in the next few slides.

  5. QIBA CT 1-C Protocol Acquisition • The phantom • Image datasets • The imaging sites • System parameters • Markup sites

  6. QIBA CT 1-C Acquisition Protocol Acquisition phantom: FDA lung phantom + NIST pocket phantom The FDA phantom accomodates 8 attached nodules, some are 20 mm in size. Left: 10 & 20 mm spheres @ - 10 & +100 HU Right: 10 & 20 mm spiculated @ - 10 & +100 HU, 10 mm ovoid, lobulated, spiculated Graded nodules coming @ 9 mm – giving 5, 8, 9, 10 mm. - The NIST pocket phantom is a free standing Lego structure with teflon balls ~ 6 mm.

  7. QIBA CT 1-C imaging sites Potential imaging sites FDA, Philips 16 row detector Nick Petrick / Marios Gavrelides, contact Duke, Ehsan Samei, Division Chief, Clinical Imaging Physics 1 GE LightSpeed VCT (64 slice), 4 GE LightSpeed 16 (16 slice, 1 with fluoroscopic capability) Johns Hopkins – Siemens, Toshiba Mahadevappa Mahesh, Chief Physicist UM-MC, Sensation 64 Siemens interested Eliot Seigel / Joseph Chen, radiologists UCLA – Mike McNitt Gray Siemens (Germany), offer of multiple scanners Mathias Thorn MSKCC Rush CRO Rad Pharm – Initiated discussion of markup. Additional sites: Perceptive Informatics, Biomedical Systems

  8. QIBA CT 1-C Protocol1st branch = a standard protocol Scan 2 - 3 times. No more the one or two are to be read. Use the developing QIBA protocol (akin to ACRIN 6678) to specify kVp, slice thickness, mAs, rotation time, pitch, reconstruction kernel (affects MTF). Include water and ACR phantoms to characterize the resolution and noise levels under this branch of the protocol.

  9. Sample Protocol Chart for ACRIN 6678

  10. QIBA CT 1-C Profiles2nd branch = performance specified Specify easily implemented PERFORMANCE metrics of resolution and noise. Guidance provided on: • kVp (affects contrast difference between materials) • Slice thickness, recon interval (affects z-axis resolution & noise) • Rotation time and pitch (coverage, breath hold, etc.) Performance required on: • Recon kernel performance - EXAMPLE: • Choose kernel such that you can see 6 or 7 (but no more than 7) lp/cm on ACR phantom….or • 10% MTF should be between 6 and 7 lp/cm • mA level performance • Choose effective mAs level so that std dev is between 20 and 30 HU in a 20 cm water phantom

  11. QIBA CT 1-C Markup Procedure Adapt the Rad-Pharm process used in QIBA volume-CT 1-A and 1-B to acquire RECIST (1D), WHO (2D), & volume (3D) reads. 5 - 6 readers 2 reads for each nodules (one repeat). Can we avoid repeat reads for the full set of series?The 1A study may provide prior estimates of intra- and inter-rater variability. Is it possible to reduce the number of reads?

  12. QIBA CT 1-C ProfileNotional sizing of study 4 sites; 2 branches to protocol (QIBA-2 profile & performance-based); 8 nodules 2 – 3 acquisitions, of which 1 or 2 are read 2 repeat reads Full factorial design implies 256 nodule reads per radiologist - too large. Aim for less than full-factorial design.

  13. Goal 3 Compare the accuracy and precision of radiologists’ measurements of RECIST and Volume for these phantom datasets. (image mask?) • RECIST vs. volume. • Investigate variance & bias. • Inter-system variation. • Intra-system variation.

  14. Goal 4 4. Determine the minimum detectable level of change that can be achieved when measuring nodules in phantom datasets.

  15. Required resources • Use of FDA phantom, water and ACR phantoms. Also NIST pocket phantom. • Select clinical image collection sites through QIBA-CT group: Offers from FDA, Duke, John’s Hopkins. Other possible sites: UMMC, MSKCC, Siemens. • Mark up similar to QIBA CT 1-A procedures at Rad-Pharm. Generates • RECIST (1D) • WHO (2D) • Segmented volume.

  16. Next steps • Refine Questions and Experimental Design. • Complete clinic recruitment. Develop protocol with associated medical physicists. • Confirm availability and arrange reading with Rad-Pharm. Other CROs are possible. • Schedule use of FDA phantom.

More Related