Multiclass Classification of Hepatic Anomalies with Dielectric Properties: From Phantom Materials to Rat Hepatic Tissues

Open-ended coaxial probes can be used as tissue characterization devices. However, the technique suffers from a high error rate. To improve this technology, there is a need to decrease the measurement error which is reported to be more than 30% for an in vivo measurement setting. This work investigates the machine learning (ML) algorithms’ ability to decrease the measurement error of open-ended coaxial probe techniques to enable tissue characterization devices. To explore the potential of this technique as a tissue characterization device, performances of multiclass ML algorithms on collected in vivo rat hepatic tissue and phantom dielectric property data were evaluated. Phantoms were used for investigating the potential of proliferating the data set due to difficulty of in vivo data collection from tissues. The dielectric property measurements were collected from 16 rats with hepatic anomalies, 8 rats with healthy hepatic tissues, and in house phantoms. Three ML algorithms, k-nearest neighbors (kNN), logistic regression (LR), and random forests (RF) were used to classify the collected data. The best performance for the classification of hepatic tissues was obtained with 76% accuracy using the LR algorithm. The LR algorithm performed classification with over 98% accuracy within the phantom data and the model generalized to in vivo dielectric property data with 48% accuracy. These findings indicate first, linear models, such as logistic regression, perform better on dielectric property data sets. Second, ML models fitted to the data collected from phantom materials can partly generalize to in vivo dielectric property data due to the discrepancy between dielectric property variability.

[1]  Alejandro Fornes-Leal,et al.  Dielectric Characterization of In Vivo Abdominal and Thoracic Tissues in the 0.5–26.5 GHz Frequency Band for Wireless Body Area Networks , 2019, IEEE Access.

[2]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[3]  F. Barnes,et al.  Handbook of biological effects of electromagnetic fields , 2007 .

[4]  Yang Hao,et al.  Broadband Tissue Mimicking Phantoms and a Patch Resonator for Evaluating Noninvasive Monitoring of Blood Glucose Levels , 2014, IEEE Transactions on Antennas and Propagation.

[5]  R. W. Lau,et al.  The dielectric properties of biological tissues: II. Measurements in the frequency range 10 Hz to 20 GHz. , 1996, Physics in medicine and biology.

[6]  C. Gabriel,et al.  Complex permittivity of sodium chloride solutions at microwave frequencies , 2007, Bioelectromagnetics.

[7]  Aart J. Nederveen,et al.  CSI-EPT: A Contrast Source Inversion Approach for Improved MRI-Based Electric Properties Tomography , 2015, IEEE Transactions on Medical Imaging.

[8]  Damijan Miklavčič,et al.  Variation in dielectric properties due to pathological changes in human liver , 2015, Bioelectromagnetics.

[9]  M. Lazebnik,et al.  Ultrawideband temperature-dependent dielectric properties of animal liver tissue in the microwave frequency range , 2006, Physics in medicine and biology.

[10]  Glenn Hefter,et al.  Dielectric relaxation of aqueous NaCl solutions , 1999 .

[11]  S. Erdamar,et al.  Machine learning aided diagnosis of hepatic malignancies through in vivo dielectric measurements with microwaves , 2016, Physics in medicine and biology.

[12]  M. Okoniewski,et al.  Precision open-ended coaxial probes for in vivo and ex vivo dielectric spectroscopy of biological tissues at microwave frequencies , 2005, IEEE Transactions on Microwave Theory and Techniques.

[13]  Barry N. Taylor,et al.  Guidelines for Evaluating and Expressing the Uncertainty of Nist Measurement Results , 2017 .

[14]  Ann P O'Rourke,et al.  Dielectric properties of human normal, malignant and cirrhotic liver tissue: in vivo and ex vivo measurements from 0.5 to 20 GHz using a precision open-ended coaxial probe , 2007, Physics in medicine and biology.

[15]  S. Standard GUIDE TO THE EXPRESSION OF UNCERTAINTY IN MEASUREMENT , 2006 .

[16]  Charles V. Sammut,et al.  Accurate in vivo dielectric properties of liver from 500 MHz to 40 GHz and their correlation to ex vivo measurements , 2016, Electromagnetic biology and medicine.

[17]  Ibrahim Akduman,et al.  Microwave dielectric property based classification of renal calculi: Application of a kNN algorithm , 2019, Comput. Biol. Medicine.

[18]  C Gabriel,et al.  Dielectric measurement: error analysis and assessment of uncertainty , 2006, Physics in medicine and biology.

[19]  Lorenzo Crocco,et al.  A method for quantitative imaging of electrical properties of human tissues from only amplitude electromagnetic data , 2019, Inverse Problems.

[20]  C Gabriel,et al.  Changes in the dielectric properties of rat tissue as a function of age at microwave frequencies. , 2001, Physics in medicine and biology.

[21]  Martin O'Halloran,et al.  Investigation of the effect of dehydration on tissue dielectric properties in ex vivo measurements , 2017 .

[22]  Charles Sammut,et al.  Dielectric properties of muscle and liver from 500 MHz–40 GHz , 2013, Electromagnetic biology and medicine.

[23]  Gérard Biau,et al.  Analysis of a Random Forests Model , 2010, J. Mach. Learn. Res..

[24]  Shiwen Yu,et al.  An Improved k-Nearest Neighbor Algorithm for Text Categorization , 2003, ArXiv.