Publications

  1. Liu, G., Jiang, W., Zheng, X. and Xue, Q. , 2021. Flow-signal correlation in seal whisker array sensing. Bioinspiration & Biomimetics,17 (01). DOI https://doi.org/10.1088/1748-3190/ac363c
  2. Jiang, W., Farbos De Luzan, C., Wang, X., Oren, L., Khosla, S., Xue, Q. and Zheng, X., 2021. Computational Modeling of Voice Production Using Excised Canine Larynx. Journal of Biomechanical Engineering. (Published online August 23, 2021)
  3. Geng, B., Movahhedi, M., Xue, Q. and Zheng, X., 2021. Vocal fold vibration mode changes due to cricothyroid and thyroarytenoid muscle interaction in a three-dimensional model of the canine larynx. The Journal of the Acoustical Society of America150(2), pp.1176–1187.
  4. Movahhedi, M., Geng, B., Xue, Q. and Zheng, X., 2021. Effects of cricothyroid and thyroarytenoid interaction on voice control: Muscle activity, vocal fold biomechanics, flow, and acoustics. The Journal of the Acoustical Society of America150(1), pp.29-42.
  5. Bodaghi, D., Jiang, W., Xue, Q. and Zheng, X., 2021. Effect of Supraglottal Acoustics on Fluid–Structure Interaction During Human Voice Production. Journal of Biomechanical Engineering143(4), p.041010.
  6. Haakansson, J., Jiang, W., Xue, Q., Zheng, X., Ding, M., Agarwal, A.A. and Elemans, C.P., 2021. Aerodynamics and motor control of ultrasonic vocalizations for social communication in mice and rats. BMC Biology.
  7. Bodaghi, D., Xue, Q., Zheng, X. and Thomson, S., 2021. Effect of Subglottic Stenosis on Vocal Fold Vibration and Voice Production Using Fluid–Structure–Acoustics Interaction Simulation. Applied Sciences11(3), p.1221.
  8. Geng, B., Pham, N., Xue, Q., and Zheng, X.(2020). A Three-Dimensional Vocal Fold Posturing Model Based on Muscle Mechanics and Magnetic Resonance Imaging of a Canine Larynx, J. Acoust. Soc. Am, 147(4), 2597-2068.
  9. Jiang, W., Rasmussen, J.H., Xue, Q., Ding, M., Ding, M., Zheng, X. and Elemans, CPH.(2020). High-fidelity Continuum Modeling Predicts Avian Voiced Sound Production, PNAS, 117(9) 4718-4723
  10. Yang, Z., Zheng, X., and Xue, Q.(2020). A Deep Neural Network Based Glottal Flow Model for Predicting Fluid-Structure Interactions during Voice Production, Applied Science, 10(2), 705-723.
  11. Wang, X., Jiang, W., Zheng, X., and Xue, Q.(2019). A Computational Study of the Effects of Vocal Fold Stiffness Parameters on Voice Production,  J. Voice. doi.org/10.1016/j.jvoice.2019.09.004
  12. Liu, G., Xue, Q., & Zheng, X. (2019). Phase-difference on seal whisker surface induces hairpin vortices in the wake to suppress force oscillation. Bioinspiration & biomimetics14(6), 066001.
  13. Jiang, W., Zheng, X. and Xue, Q., 2019. Influence of vocal fold cover layer thickness on its vibratory dynamics during voice production. The Journal of the Acoustical Society of America146(1), pp.369-380.
  14. Liu, G., Geng, B., Zheng, X., Xue, Q., Dong, H. and Lauder, G.V., 2019. An image-guided computational approach to inversely determine in vivo material properties and model flow-structure interactions of fish fins. Journal of Computational Physics392, pp.578-593.
  15. Jiang, W., Xue, Q. and Zheng, X., 2018. Effect of longitudinal variation of vocal fold inner layer thickness on fluid-structure interaction during voice production. Journal of biomechanical engineering140(12), p.121008.
  16. Geng, B., Zheng, X., Xue, Q., Liu, G. and Dong, H., 2018. A Numerical Study of the Sound and Force Production of Flexible Insect Wings. Fluids3(4), p.87.
  17. Pham, N., Xue, Q. and Zheng, X., 2018. Coupling between a fiber-reinforced model and a Hill-based contractile model for passive and active tissue properties of laryngeal muscles: A finite element study. The Journal of the Acoustical Society of America144(3), pp.EL248-EL253.
  18. Geng, B., Xue, Q., Zheng, X., Liu, G., Ren, Y. and Dong, H., 2017. The effect of wing flexibility on sound generation of flapping wings. Bioinspiration & biomimetics, 13(1), p.016010.
  19. Xue, Q. and Zheng, X., 2017. The effect of false vocal folds on laryngeal flow resistance in a tubular three-dimensional computational laryngeal model. Journal of Voice, 31(3), pp.275-281.
  20. Geng, B., Xue, Q. and Zheng, X.(2017). “A finite element study on the cause of vocal fold vertical stiffness variation”, J. Acoust. Soc. Am. 141(4), Published online. pdf
  21. Jiang, W., Zheng, X. and Xue, Q(2017) . “Computational Modeling of Fluid-Structure-Acoustics Interaction During Voice Production”, Frontiers in Bioengineering and Biotechnology, Accepted pdf
  22. Geng, B., Xue, Q. and Zheng, X. (2016). “The effect of vocal fold vertical stiffness variation on voice production,” J. Acoust. Soc. Am. 140(4), 2856-2866.pdf
  23. Xue, Q. and Zheng, X. (2016). “The Effect of False Vocal Folds on Laryngeal Flow Resistance in a Tubular Three-dimensional Computational Laryngeal Model,” J. Voice. pdf.
  24. Xue, Q. and Zheng, X. (2014). “Intraglottal Flow Behavior in a CT-Based Laryngeal Model,” Austin Otolaryngology, 1(4), 1-7.
  25. Zheng, X., Xue, Q. and Mittal, R. (2014) “Computational Study of Hemodynamic Effects of Abnormal E/A ratio on LV Filling,”, J. Biomech Eng, 136(6), 061005-1-10. pdf
  26. Xue, Q., Zheng, X., Mittal, R. and Bielamowicz, S. (2014). “Computational Study of Effects of Tension Imbalance on Phonation in a Three Dimensional Tubular Larynx Model,” J. Voice. J. Voice. 28(4), 411-419. pdf
  27. Xue, Q., Zheng, X., Mittal, R. and Bielamowicz, S. (2014) “Subject-Specific Computational Modeling of Human Phonation,” J. Acoust. Soc. Am. 135(2), 1445-1456. pdf
  28. Mansi, T., Voigt, I, Gerogescu, B., Zheng, X., ., Mengue EA, HackL M, Ionasec, RI, Noack T, Seeburger, T and and Comaniciu, D.(2012) “An Integrated Framework for Finite-Element Modeling of Mitral Valve Biomechanics from Medical Images Application to MitralClip Intervention Planning”, Medical Image Analysis, Vol. 16, No. 7, pp:1330-1346. pdf
  29. Zheng, X., Seo, J., Vedula, V., Abraham, T., and Mittal, R. (2012) “Computational Modeling and Analysis of Intracardiac Flows in a Simple Model of Left Ventricle”, European Journal of Mechanics-B /Fluids, Vol. 35, pp: 31-39, 2012.  pdf
  30. Xue, Q., Mittal, R., Zheng, X. and Bielamowicz, S. (2012) “Computational Modeling of Phonatory Dynamics a Tubular Three-Dimensional model,” J. Acoustical Society of America, Vol. 132, No 3, pp. 1602-1613. pdf
  31. Mittal, R., Zheng, X., Bhardwaj, R., Seo, J., Xue, Q., and Bielamowicz, S. (2011) “Towards A Simulation-Based Tool for the Treatment of Vocal Fold Paralysis,” Frontiers in Computational Physiology and Medicine, Vol. 2, No. 19. pdf
  32. Zheng, X., Mittal, R., Xue, Q. and Bielamowicz, S. (2011) “Direct-Numerical Simulation of the Glottal Jet and Vocal-Fold Dynamics in a Three-Dimensional Laryngeal Model,” J. Acoustical Society of America, Vol. 130, No. 1, pp.404-415. pdf
  33. Xue, Q., Zheng, X., Mittal, R., and Bielamowicz, S. (2011) “Sensitivity of Vocal-Fold Vibratory Modes to their Three-Layer Structure: Implication for Simulation Based Phonosurgical Planning,” J. Acoustical Society of America, Vol. 130, No. 2, pp.965-976. pdf
  34. Zheng, X., Mittal, R. and Bielamowicz, S. (2011) “A Computational Study of Asymmetric Glottal Jet Deflection During Phonation,” J. Acoustical Society of America, Vol. 129, No. 4, pp.2133-2143. pdf
  35. Zheng, X., Xue, Q., Mittal, R. and Bielamowicz, S. (2010) “A Coupled Sharp-Interface Immersed-Boundary-Finite-Element Method for Flow-Structure Interaction with Application to Human Phonation,” J. Biomechanical Engineering, Vol. 132, No. 11, pp. 111003-1-12. pdf
  36. Xue, Q., Mittal, R., Zheng, X. and Bielamowicz, S. (2010) “A Computational Study of the Effect of Vocal-fold Asymmetry on Phonation,” J. Acoustical Society of America, Vol. 128, No. 2, pp. 818-827. pdf
  37. Zheng, X., Bielamowicz, S., Luo, H., and Mittal, R. (2009) “Computational Study of the Effect of False Vocal Folds on Glottal Flow and Vocal Fold Vibration During Phonation,” Annals of Biomedical Engineering, Vol. 37, No. 3, pp.625-642.  pdf
  38. Luo, H., Mittal, R., Zheng, X., Bielamowicz, S., Walsh, R., and Hahn, J. (2008) “An Immersed-Boundary Method for Flow-Structure Interaction in Biological Systems with Application to Phonation,” J. Computational Physics, Vol. 27, No. 22, pp. 9303-9332.  pdf