Quantitative ultrasound characterization of locally advanced breast cancer by estimation of its scatterer properties.

PURPOSE Tumor grading is an important part of breast cancer diagnosis and currently requires biopsy as its standard. Here, the authors investigate quantitative ultrasound parameters in locally advanced breast cancers that can potentially separate tumors from normal breast tissue and differentiate tumor grades. METHODS Ultrasound images and radiofrequency data from 42 locally advanced breast cancer patients were acquired and analyzed. Parameters related to the linear regression of the power spectrum--midband fit, slope, and 0-MHz-intercept--were determined from breast tumors and normal breast tissues. Mean scatterer spacing was estimated from the spectral autocorrelation, and the effective scatterer diameter and effective acoustic concentration were estimated from the Gaussian form factor. Parametric maps of each quantitative ultrasound parameter were constructed from the gated radiofrequency segments in tumor and normal tissue regions of interest. In addition to the mean values of the parametric maps, higher order statistical features, computed from gray-level co-occurrence matrices were also determined and used for characterization. Finally, linear and quadratic discriminant analyses were performed using combinations of quantitative ultrasound parameters to classify breast tissues. RESULTS Quantitative ultrasound parameters were found to be statistically different between tumor and normal tissue (p < 0.05). The combination of effective acoustic concentration and mean scatterer spacing could separate tumor from normal tissue with 82% accuracy, while the addition of effective scatterer diameter to the combination did not provide significant improvement (83% accuracy). Furthermore, the two advanced parameters, including effective scatterer diameter and mean scatterer spacing, were found to be statistically differentiating among grade I, II, and III tumors (p = 0.014 for scatterer spacing, p = 0.035 for effective scatterer diameter). The separation of the tumor grades further improved when the textural features of the effective scatterer diameter parametric map were combined with the mean value of the map (p = 0.004). CONCLUSIONS Overall, the binary classification results (tumor versus normal tissue) were more promising than tumor grade assessment. Combinations of advanced parameters can further improve the separation of tumors from normal tissue compared to the use of linear regression parameters. While the linear regression parameters were sufficient for characterizing breast tumors and normal breast tissues, advanced parameters and their textural features were required to better characterize tumor subtypes.

[1]  Wagner Coelho de Albuquerque Pereira,et al.  Characterization of in vitro healthy and pathological human liver tissue periodicity using backscattered ultrasound signals. , 2006, Ultrasound in medicine & biology.

[2]  Olsi Rama,et al.  Development of ultrasound tomography for breast imaging: technical assessment. , 2005, Medical physics.

[3]  W D O'Brien,et al.  Quantifying B‐mode images of in vivo rat mammary tumors by the frequency dependence of backscatter. , 2001, Journal of ultrasound in medicine : official journal of the American Institute of Ultrasound in Medicine.

[4]  Yan Bige,et al.  Analysis of microstructural alterations of normal and pathological breast tissue in vivo using the AR cepstrum. , 2006, Ultrasonics.

[5]  V. Reuter,et al.  Typing of prostate tissue by ultrasonic spectrum analysis , 1996, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[6]  E. Madsen,et al.  Interlaboratory Comparison of Backscatter Coefficient Estimates for Tissue-Mimicking Phantoms: , 2010 .

[7]  M. Oelze,et al.  Advanced Ultrasonic Imaging Techniques for Breast Cancer Research 1 , 2005 .

[8]  F. G. Sommer,et al.  Ultrasonic Characterization of Tissue Structure in the In Vivo Human Liver and Spleen , 1984, IEEE Transactions on Sonics and Ultrasonics.

[9]  M. Oelze,et al.  Examination of cancer in mouse models using high-frequency quantitative ultrasound. , 2006, Ultrasound in medicine & biology.

[10]  Michael C. Kolios,et al.  Quantitative Ultrasound Characterization of Responses to Radiotherapy in Cancer Mouse Models , 2009, Clinical Cancer Research.

[11]  E. Feleppa,et al.  Relationship of Ultrasonic Spectral Parameters to Features of Tissue Microstructure , 1987, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[12]  H. Bloom,et al.  Histological Grading and Prognosis in Breast Cancer , 1957, British Journal of Cancer.

[13]  Victor C. Anderson,et al.  Sound Scattering from a Fluid Sphere , 1950 .

[14]  Mark R Holland,et al.  Characterization of Anisotropic Myocardial Backscatter Using Spectral Slope, Intercept and Midband Fit Parameters , 2007, Ultrasonic imaging.

[15]  Robert M. Haralick,et al.  Textural Features for Image Classification , 1973, IEEE Trans. Syst. Man Cybern..

[16]  T J Hall,et al.  Parametric Ultrasound Imaging from Backscatter Coefficient Measurements: Image Formation and Interpretation , 1990, Ultrasonic imaging.

[17]  P. Schattner,et al.  Ultrasound Tissue Characterization of Breast Biopsy Specimens , 1991 .

[18]  T. Stephens Missed Breast Cancers at US-guided Core Needle Biopsy: How to Reduce Them , 2011 .

[19]  Jenho Tsao,et al.  Mean scatterer spacing estimation using wavelet spectrum [ultrasonic biological tissue characterization applications] , 2004, IEEE Ultrasonics Symposium, 2004.

[20]  F. Foster,et al.  Frequency dependence of ultrasound attenuation and backscatter in breast tissue. , 1986, Ultrasound in medicine & biology.

[21]  Tomy Varghese,et al.  Characterization of Tissue Microstructure Scatterer Distribution with Spectral Correlation , 1993, Ultrasonic imaging.

[22]  Pascal Laugier,et al.  Three-dimensional high-frequency characterization of cancerous lymph nodes. , 2010, Ultrasound in medicine & biology.

[23]  D J Coleman,et al.  A model for acoustic characterization of intraocular tumors. , 1985, Investigative ophthalmology & visual science.

[24]  E. Feleppa,et al.  Quantitative ultrasound in cancer imaging. , 2011, Seminars in oncology.

[25]  E. Madsen,et al.  Tissue mimicking materials for ultrasound phantoms. , 1978, Medical physics.

[26]  Chih-Kuang Yeh,et al.  Classification of scattering media within benign and malignant breast tumors based on ultrasound texture-feature-based and Nakagami-parameter images. , 2011, Medical physics.

[27]  Michael C. Kolios,et al.  Quantitative ultrasound for the monitoring of novel microbubble and ultrasound radiosensitization. , 2012, Ultrasound in medicine & biology.

[28]  R. F. Wagner,et al.  Describing small-scale structure in random media using pulse-echo ultrasound. , 1990, The Journal of the Acoustical Society of America.

[29]  L. X. Yao,et al.  Backscatter Coefficient Measurements Using a Reference Phantom to Extract Depth-Dependent Instrumentation Factors , 1990, Ultrasonic imaging.

[30]  S. Giordano,et al.  Update on locally advanced breast cancer. , 2003, The oncologist.

[31]  Xiaoyan Tang,et al.  Ultrasound scatter-spacing based diagnosis of focal diseases of the liver , 2007, Biomed. Signal Process. Control..

[32]  N. Duric,et al.  In vivo breast sound-speed imaging with ultrasound tomography. , 2009, Ultrasound in medicine & biology.

[33]  Ronald H. Silverman,et al.  Ultrasonic spectrum analysis for tissue assays and therapy evaluation , 1997, Int. J. Imaging Syst. Technol..

[34]  Sung Hyun Kim,et al.  Correlation of ultrasound findings with histology, tumor grade, and biological markers in breast cancer , 2008, Acta oncologica.

[35]  William D. O'Brien,et al.  Differentiation and characterization of rat mammary fibroadenomas and 4T1 mouse carcinomas using quantitative ultrasound imaging , 2004, IEEE Transactions on Medical Imaging.

[36]  R. F. Wagner,et al.  Application of autoregressive spectral analysis to cepstral estimation of mean scatterer spacing , 1993, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[37]  F. Lizzi,et al.  Ultrasonic spectrum analysis for tissue assays and therapy evaluation , 1997 .

[38]  Yassin Labyed,et al.  A theoretical comparison of attenuation measurement techniques from backscattered ultrasound echoes. , 2011, The Journal of the Acoustical Society of America.

[39]  U R Abeyratne,et al.  Wavelet transforms in estimating scatterer spacing from ultrasound echoes. , 2000, Ultrasonics.

[40]  K. Suzuki,et al.  Evaluation of structural change in diffuse liver disease with frequency domain analysis of ultrasound , 1993, Hepatology.