Paul Licato

Systems and methods for displaying multi-energy data

U.S. Patent # 8,115,784

2012

Method of CT perfusion imaging and apparatus for implementing same

U.S. Patent # 7,933,377

2011

Systems and methods for automated diagnosis

U.S. Patent # 8,233,684

2012

Systems and methods for improving a resolution of an image

U.S. Patent # 7,466,790

2008

Methods and apparatus for reducing noise in images

U.S. Patent # 8,155,466

2012

Magnetic resonance imaging with nested gradient pulses

U.S. Patent # 7,047,062

2006

Method and system for performing high temporal resolution bolus detection using CT image projection data

U.S. Patent # 7,983,460

2011

Modular time masking sequence programming for imaging system

U.S. Patent # 6,788,055

2004

Prediction methods and apparatus

U.S. Patent # 7,606,614

2009

Modular time masking sequence programming for imaging system

U.S. Patent # 6,249,120

2001

Real-time MR section cross-reference on replaceable MR localizer images

U.S. Patent # 6,108,573

2000

Graphic application development system for a medical imaging system

U.S. Patent # 7,020,868

2006

Method for producing physical gradient waveforms in magnetic resonance imaging

U.S. Patent # 6,008,648

1999

Method and apparatus for managing workflow in prescribing and processing medical images

U.S. Patent # 7,020,844

2006

Method for producing an off-center image using an EPI pulse sequence

U.S. Patent # 5,689,186

1997

Nutation angle measurement during MRI prescan

U.S. Patent # 5,416,412

1995

Method and apparatus for defining a three-dimensional imaging

U.S. Patent # 6,757,417

2004

Method and apparatus for managing peripheral devices in a medical imaging system

U.S. Patent # 6,356,780

2002

System architecture for medical imaging systems

U.S. Patent # 6,348,793

2002

Initial use of fast switched dual energy CT for coronary artery disease

Pavlicek, W., Panse, P., Hara, A., Boltz, T., Paden, R., Yamak, D., Licato, P., Chandra, N., Okerlund, D., Dutta, S., Bhotika, R.

2010

Coronary CT Angiography (CTA) is limited in patients with calcified plaque and stents. CTA is unable to confidently differentiate fibrous from lipid plaque. Fast switched dual energy CTA offers certain advantages. Dual energy CTA removes calcium thereby improving visualization of the lumen and potentially providing a more accurate measure of stenosis. Dual energy CTA directly measures calcium burden (calcium hydroxyapatite) thereby eliminating a separate non-contrast series for Agatston Scoring. Using material basis pairs, the differentiation of fibrous and lipid plaques is also possible. Patency of a previously stented coronary artery is difficult to visualize with CTA due to resolution constraints and localized beam hardening artifacts. Monochromatic 70 keV or Iodine images coupled with Virtual Non-stent images lessen beam hardening artifact and blooming. Virtual removal of stainless steel stents improves assessment of in-stent re-stenosis. A beating heart phantom with 'cholesterol' and 'fibrous' phantom coronary plaques were imaged with dual energy CTA. Statistical classification methods (SVM, kNN, and LDA) distinguished 'cholesterol' from 'fibrous' phantom plaque tissue. Applying this classification method to 16 human soft plaques, a lipid 'burden' may be useful for characterizing risk of coronary disease. We also found that dual energy CTA is more sensitive to iodine contrast than conventional CTA which could improve the differentiation of myocardial infarct and ischemia on delayed acquisitions. These phantom and patient acquisitions show advantages with using fast switched dual energy CTA for coronary imaging and potentially extends the use of CT for addressing problem areas of non-invasive evaluation of coronary artery disease.

View more

Multi-material decomposition of spectral CT images

Mendonça, P.R., Bhotika, R., Maddah, M., Thomsen, B., Dutta, S., Licato, P.E., Joshi, M.C.

2010

Spectral Computed Tomography (Spectral CT), and in particular fast kVp switching dual-energy computed tomography, is an imaging modality that extends the capabilities of conventional computed tomography (CT). Spectral CT enables the estimation of the full linear attenuation curve of the imaged subject at each voxel in the CT volume, instead of a scalar image in Hounsfield units. Because the space of linear attenuation curves in the energy ranges of medical applications can be accurately described through a two-dimensional manifold, this decomposition procedure would be, in principle, limited to two materials. This paper describes an algorithm that overcomes this limitation, allowing for the estimation of N-tuples of material-decomposed images. The algorithm works by assuming that the mixing of substances and tissue types in the human body has the physicochemical properties of an ideal solution, which yields a model for the density of the imaged material mix. Under this model the mass attenuation curve of each voxel in the image can be estimated, immediately resulting in a material-decomposed image triplet. Decomposition into an arbitrary number of pre-selected materials can be achieved by automatically selecting adequate triplets from an application-specific material library. The decomposition is expressed in terms of the volume fractions of each constituent material in the mix; this provides for a straightforward, physically meaningful interpretation of the data. One important application of this technique is in the digital removal of contrast agent from a dual-energy exam, producing a virtual nonenhanced image, as well as in the quantification of the concentration of contrast observed in a targeted region, thus providing an accurate measure of tissue perfusion.

View more