Manufacturing Technology 2024, 24(3):458-464 | DOI: 10.21062/mft.2024.048

Accuracy of Photogrammetric Models for 3D printed Wrist-hand Orthoses

Tuong Nguyen Van ORCID...1, Natasa Naprstkova ORCID...2
1 Faculty of Mechanical Engineering, Nha Trang University. 02 Nguyen Dinh Chieu, Nha Trang, Vietnam
2 Faculty of Mechanical Engineering, University of Jan Evangelista in Ústí nad Labem. Pasteurova 3334/7, 400 01 Usti nad Labem, Czech Republic

Today, 3D printed wrist-hand orthoses can be used to immobilize the arms instead of plaster or fi-berglass casts. Typically, 3D arm models for modelling wrist-hand orthoses can be created using a 3D scanning system. Our previous study shows that smartphone cameras and photogrammetry tech-niques can be used instead of professional 3D scanning systems, but the accuracy of the photogram-metric models has not yet been fully investigated. This paper presents the results of accuracy verifica-tion of arm models reconstructed from 2D images captured with a smartphone camera. The forearm and wrist-hand parts of a photogrammetric model were subjected to a virtual inspection by compar-ing them with the corresponding parts of an arm model created with a 3D scanner. In addition, a physical verification was carried out by assessing the contact between the arm of interest and an ac-tual 3D printed wrist-hand orthosis that was created with reference to the photogrammetric model. The test results show that the photogrammetric models achieve the necessary accuracy to serve as reference models for the construction of 3D printed wrist-hand orthoses.

Keywords: Photogrammetry, 3D printed, Wrist-Hand Orthoses, Smartphone

Received: January 13, 2024; Revised: May 13, 2024; Accepted: May 15, 2024; Prepublished online: May 15, 2024; Published: July 1, 2024  Show citation

ACS AIP APA ASA Harvard Chicago IEEE ISO690 MLA NLM Turabian Vancouver
Van TN, Naprstkova N. Accuracy of Photogrammetric Models for 3D printed Wrist-hand Orthoses. Manufacturing Technology. 2024;24(3):458-464. doi: 10.21062/mft.2024.048.
Download citation

References

  1. VAN, T.N., LE THANH, T., VAN, T.N., NAPRSTKOVA, N. (2023). Smartphone-based Data Acquisition Method for Modelling 3D Printed Arm Casts. In: Manufacturing Technology Journal, Vol. 23, No. 2, pp. 260-267. J. E. Purkyně University in Usti nad Labem, Czech Republic. ISSN 1213-2489 Go to original source...
  2. KELLER, M., GUEBELI, A., THIERINGER, F., HONIGMANN, P. (2021). In-hospital Professional Production of Patient-specific 3D-printed Devices for Hand and Wrist Rehabilitation. In: Hand Surgery Rehabilitation, Vol. 40, No. 2, pp. 126-133. Elsevier, Amsterdam, The Netherlands. ISSN 2468-1210 Go to original source...
  3. VAN LIESHOUT, E. M. M., VERHOFSTAD, M. H. J., BEENS, L. M., VAN BEKKUM, J. J. J., WILLEMSEN, F., JANZING, H. M. J., & VAN VLEDDER, M. G. (2022). Personalized 3D-printed Forearm Braces as an Alternative for a Traditional Plaster Cast or Splint; A Systematic Review. In: Inju-ry, Vol. 53 Suppl. 3, pp. S47-S52. Elsevier, Amsterdam, Netherlands. ISSN 0020-1383 Go to original source...
  4. LAZZERI, S., TALANTI, E., BASCIANO, S., BARBATO, R., FONTANELLI, F., UCCHEDDU, F., SERVI, M., VOLPE, Y., VAGNOLI, L., AMORE, E., MARZOLA, A., MCGREEVY, K. S., CARFAGNI, M. (2022). 3D-Printed Patient-Specific Casts for the Distal Radius in Children: Outcome and Pre-Market Survey. In: Materials, Vol. 15, No. 8, 2863. MPI, (Basel, Switzerland), ISSN 1996-1944 Go to original source...
  5. POPESCU, D., BACIU, F., VLĂSCEANU, D., MARINESCU, R., LĂPTOIU, D. (2023). Investigations on the Fatigue Behaviour of 3D-Printed and Thermoformed Polylactic Acid Wrist-Hand Orthoses. In: Polymers, Vol. 15, NO. 12, 2737. MDPI, Basel, Switzerland, ISSN 2073-4360 Go to original source...
  6. JAN, Z., ABAS, M., KHAN, I., QAZI, M. I., USMAN JAN, Q. M. (2023). Design and Analysis of Wrist Hand Orthosis for Carpal Tunnel Syndrome using Additive Manufacturing, In: Journal of Engineering Research, Vol. 12, 001. Elsevier, Amsterdam, The Netherlands. ISSN 2307-1877 Go to original source...
  7. SEDLAK, J., HRUSECKA, D., CHROMJAKOVA, F., MAJERIK, J. & BARENYI, I. (2021). Analysis of the Wear on Machined Groove Profiles Using Reverse Engineering Technology. In: Manufacturing Technology, Vol. 21, No. 4, pp. 529-38. J. E. Purkyně University in Usti nad Labem, Czech Republic. ISSN 1213-2489 Go to original source...
  8. FABIAN, M., HUŇADY, R. & KUPEC, F. (2022). Reverse Engineering and Rapid Prototyping in the Process of Developing Prototypes of Automotive Parts. In: Manufacturing Technology, Vol. 22, No. 6, pp. 669-78. J. E. Purkyně University in Usti nad Labem, Czech Republic. ISSN 1213-2489 Go to original source...
  9. BECHNÝ, V., MATUŠ, M., JOCH, R., DRBÚL, M., HOLUBJÁK, J., CZÁN, A., ŠAJGALÍK, M. & MARKOVIČ, J. (2023). Design of an Injection Mould Utilizing Experimental Measurements and Reverse Engineering. In: Manufacturing Technology, Vol. 23, No. 5, pp. 597-603. J. E. Purkyně University in Usti nad Labem, Czech Republic. ISSN 1213-2489 Go to original source...
  10. CHEN, Y., LIN, H., YU, Q., ZHANG, X., WANG, D., SHI, L., HUANG, W., ZHONG, S. (2020). Application of 3D-Printed Orthopedic Cast for the Treatment of Forearm Fractures: Finite Element Analysis and Comparative Clinical Assessment. In: BioMed Research International, Vol. 2020, Article ID 9569530. Hindawi Publishing Corporation, Cairo, Egypt. ISSN 2314-6141 Go to original source...
  11. VAN, T.N., LE THANH, T., NAPRSTKOVA, N. (2021). Measuring propeller pitch based on photogrammetry and CAD. In: Manufacturing Technology, Vol. 21, No. 5, pp.706-713. J. E. Purkyně University in Usti nad Labem, Czech Republic. ISSN 1213-2489 Go to original source...
  12. TUONG, N.V. (2018), Manufacturing Method of Spiral Bevel Gears Based on CAD/CAM and 3-Axis Machining Center. In: MM Science Journal, Vol. June 2018, pp. 2401-2405. MM Publishing, Czech Republic. ISSN 1803-1269 Go to original source...
  13. MENDRICKY, R., SOBOTKA, J. (2020). Accuracy Comparison of the Optical 3D Scanner and CT Scanner. In: Manufacturing Technology. Vol. 20, No. 6, pp. 791-801. J. E. Purkyně University in Usti nad La-bem, Czech Republic. ISSN 1213-2489 Go to original source...
  14. TUONG N. V. (2023). Design and Manufacture 3D Printed Arm Cast from Data Taken by Smartphone. Research report, Nha Trang University, Viet Nam
  15. SALVADOR, T., SLAGLE, J., CHAPRNKA, G., AGRONIN, M, OETGEN, M., TABAIE, S., CLEARY, K, DAYAL, A., Development of a Novel Photogrammetry Method for Acquiring 3D Surface Models of Infant Clubfoot Anatomy. In: Medical Imaging 2022: Image-Guided Procedures, Robotic Interventions, and Modelling, Vol. 12034, 120342E-3. SPIE, Washington USA, ISBN 9781510649446 Go to original source...
  16. OLIVIER, M. (2019). A Low-Cost Custom Knee Brace via Smartphone Photogrammetry. Master thesis, University of Ottawa. Ottawa, Canada
  17. HERNANDEZ, A., LEMAIRE, E. (2017). A Smartphone Photogrammetry Method for Digitizing Pros-thetic Socket Interiors. In: Prosthetics and Orthotics International, Vol. 41, No. 2, pp. 210-214. SAGE Publications, California, United States. ISSN 1746-1553 Go to original source...
  18. TURSI, A., KURILLO, G., BAJCSY, R. (2017). Automatic Detection of Body Landmarks in Human Body Scans - Lower Limb Analysis for Biomedical and Footwear Applications. In: The 8th International Conference and Exhibition on 3D Body Scanning and Processing Technologies, pp. 179-191. Montreal QC, Canada. ISBN 978-3-033-06436-2 Go to original source...
  19. PALOUŠEK, D., ROSICKÝ, J., KOUTNÝ, D., STOKLÁSEK, P., NÁVRAT, T. (2014). Pilot Study of the Wrist Orthosis Design Process. In: Rapid Prototyping Journal, Vol. 20, No. 1, pp. 27-32. Emerald Group Publishing Ltd., United Kingdom. ISSN 1355-2546 Go to original source...
  20. BARONIO, G., HARRAN, S., SIGNORONI, A. (2016). A Critical Analysis of a Hand Orthosis Reverse Engineering and 3D Printing Process. In: Applied Bionics & Biomechanics, Vol. 2016, Article ID 8347478. Hindawi Limited, London, United Kingdom. ISSN 17542103 Go to original source...

This is an open access article distributed under the terms of the Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0), which permits non-comercial use, distribution, and reproduction in any medium, provided the original publication is properly cited. No use, distribution or reproduction is permitted which does not comply with these terms.