1. Chang R., Johnson P., Stafford C., and Hwang J.. (2012). "Fabrication and Characterization of a Multilayered Optical Tissue Model with Embedded Scattering Microspheres in Polymeric Materials", Biomedical Optics Express, 6 (3), 1326-1339.
  2. Litorja M., Chang R., Hwang J., Allen D., Zuzak K., Wehner E., Best S., Livingston E., and Caddedu J.. (2012). "Calibration and validation scheme for in vivo spectroscopic imaging of tissue oxygenation", Oxygen Transport to Tissue XXXIV, Advances in Experimental Biology and Medicine (New York, NY).
  3. Lee J.Y., Clarke M.L., Tokumasu F., Lesoine J.F., Allen D.W., Chang R., Litorja M., and Hwang J.. (2011). "Absorption-Based Hyperspectral Imaging and Analysis of Single Erythrocytes", IEEE Journal of Selected Topics in Quantum Electronics, (99), 1-10.
  4. Chang R., Emami K., Jeevarajan A., Wu H., and Sun W.. (2011). "Direct Cell Writing of 3D Micro-organ for Drug Metabolism Studies", Biofabrication, 4 (2), 1-11.
  5. Chang R., Nam J., and Sun W.. (2008). "Direct Cell Writing of 3D Micro-organ for In Vitro Pharmacokinetic Model", Tissue Engineering Part C, 2 (14), 157-169.
  6. Chang R., Nam J., and Sun W.. (2008). "Computer-Aided Design, Modeling, and Freeform Fabrication of Micro-organ Flow Patterns for Pharmacokinetic Study", CAD Applications, 5 21-29.
  7. Chang R., Nam J., and Sun W.. (2008). "Effects of Dispensing Pressure and Nozzle Diameter on Cell Survival from Solid Freeform Fabrication-based Direct Cell Writing", Tissue Engineering, 1 (14), 41-48.
  8. Buyukhatipoglu K., Chang R., Sun W., and Morss Clyne A.. (2010). "Bioprinted Nanoparticles for Tissue Engineering Applications", Tissue Engineering Part C, 4 (16), 631-642.
  9. Shor L., Guceri S., Chang R., Sun W., Gordon J., Kang Q., Hartstock L., and An Y.. (2009). "Precision Extruding Deposition (PED) Fabrication of Poly-e-Caprolactone (PCL) Scaffolds for Bone Tissue Engineering", Biofabrication, 1 (1), 1-10.
  10. Tourlomousis F. & Chang R.. (2015). "Computational Modeling of 3D Printed Tissue-on-a-Chip Microfluidic Devices as Drug Screening Platforms", 2014 ASME International Mechanical Engineering Congress & Exposition, Volume 3: Biomedical & Biotechnology Engineering, Montreal, Quebec, Canada, ISBN: 978-0-7918-4646-9. (Paper No. IMECE2014-38454, 9 pages, doi:10.1115/IMECE2014-38454).
  11. Tourlomousis F., Babakanov A., Ding H. & Chang R.. (2015). "A novel Melt Electrospinning System for Studying Cell Substrate Interactions", 2015 ASME Manufacturing Science & Engineering Conference, Charlotte, North Carolina, USA . (accepted for publication and presentation)
  12. Ding H. & Chang R. (2015). "Comparison of Photometric Stereo and Spectral Analysis for Visualization and Assessment of Burn Injury from Hyperspectral Imaging", 2015 IEEE International Conference on Computational Intelligence and Virtual Environments for Measurement Systems and Applications (CIVEMSA), Shenzhen, China. (accepted for publication and presentation)
  13. Chang R., Tourlomousis F.. (2015)."Organ Printing", Zhang L.G. & Fischer J.P. & Leong K.W., 3D Bioprinting and Nanotechnology in Tissue Engineering and Regenerative Medicine,  Academic PressElsevier., ISBN: 9780128005477. 333-347.
  14. Tourlomousis F. and Chang R.. (2015)."Numerical Investigation of Dynamic Microorgan Devices as Drug Screening Platforms: Part I: Macroscale Modeling Approach & Validation", Biotechnology & Bioengineering, Wiley.  DOI: 10.1002/bit.25822
  15. Tourlomousis F. and Chang R.. (2015)."Numerical Investigation of Dynamic Microorgan Devices as Drug Screening Platforms: Part II: Microscale Modeling Approach & Validation", Biotechnology & Bioengineering, Wiley. DOI: 10.1002/bit.25824
  16. Tourlomousis F., Ding H.,  Dole A. and Chang R. (2016). " Towards Resolution Enhancement and Process Repeatability With a Melt Electrospinning Writing Process: Design and Protocol Considerations",  11th International Manufacturing Science and Engineering Conference, At Virginia Tech, Blacksburg, USA, Volume: 2 - Biomanufacturing: Advances in Additive Biomanufacturing of Tissues and Multiscale Engineered Tissue Constructs.  DOI link
  17. Tourlomousis F., Ding H., Dilhan K. and Chang R. (2017). "Melt Electrospinning Writing Process Guided by a 'Printability Number'", Journal of Manufacturing Science and Engineering. DOI link
  18. Ding H., Tourlomousis F. and Chang R. (2017). "Bioprinting Multidimensional Constructs: A Quantitative Approach to Understanding Printed Cell Density and Redistribution Phenomena", Biomedical Physics & Engineering ExpressDOI link
  19. Tourlomousis F. and Chang R. (2017). "Dimensional Metrology of Cell - Matrix Interactions", CIRP Procedia. DOI link
  20. Ding H., Tourlomousis F. and Chang R. (2017). "A Methodology for Quantifying Cell Density and Distribution in Multidimensional Bioprinted Gelatin-Alginate Constructs". Journal of Manufacturing Science and Engineering. DOI link
  21. Ding, H., & Chang, R. C. (2018). Printability Study of Bioprinted Tubular Structures Using Liquid Hydrogel Precursors in a Support Bath. Applied Sciences8(3), 403. DOI link
  22. Ding, H., & Chang, R. C. (2018). Hyperspectral Imaging With Burn Contour Extraction for Burn Wound Depth Assessment. Journal of Engineering and Science in Medical Diagnostics and Therapy, 1(4), 041002. DOI link
  23. Ding, H., & Chang, R. C. (2018). Simulating image-guided in situ bioprinting of a skin graft onto a phantom burn wound bed.Additive Manufacturing. 22.708-719. DOI link
  24. Ding, H., Cao, K., Zhang, F., Boettcher, W., Chang, R.C. (2019).A Fundamental Study of Charge Effects on Melt Electrowritten Polymer Fibers. Materials & Design. 178.107875.  DOI link 
  25. Tourlomousis, F., Jia, C., Karydis, T., Mershin, A., Wang, H., Kalyon, D. M., & Chang, R. C. (2019). Machine learning metrology of cell confinement in melt electrowritten three-dimensional biomaterial substrates. Microsystems & nanoengineering, 5(1), 15.