Hybrid Modified Cubic-Honeycomb-Plate Structure: A Novel Bone Regeneration Scaffold with Enhanced Mechanical Stiffness Achieved Through High Printing Fidelity

doi:10.1007/s42235-025-00733-5

Journal of Bionic Engineering ›› 2025, Vol. 22 ›› Issue (4): 1881-1909.doi: 10.1007/s42235-025-00733-5

Hybrid Modified Cubic-Honeycomb-Plate Structure: A Novel Bone Regeneration Scaffold with Enhanced Mechanical Stiffness Achieved Through High Printing Fidelity

Rigoberto Lopez Reyes1；Min-Soo Ghim2；Eun Chae Kim1；Nae-Un Kang1；Dongwoo Sohn3；Young-Sam Cho4,5

1 Department of Mechanical Engineering, WonkwangUniversity, 460 Iksandae-ro, Iksan, Jeonbuk54538, Republic of Korea 2 Glopex Co., Ltd, 677-12 Dongtandae-ro, Hwaseong,Gyeonggido, Republic of Korea 3 Division of Mechanical Engineering, Korea Maritime andOcean University, 727 Taejong-ro, Yeongdo-gu,Busan 49112, Republic of Korea
4 Division of Mechanical Engineering, Wonkwang University,460 Iksandae-ro, Iksan, Jeonbuk 54538, Republic of Korea
5 MECHABIO Group, Wonkwang University, 460 Iksandaero, Iksan, Jeonbuk 54538, Republic of Korea

Online:2025-06-19 Published:2025-08-31
Contact: Young-Sam Cho E-mail:youngsamcho@wku.ac.kr
About author:Rigoberto Lopez Reyes1；Min-Soo Ghim2；Eun Chae Kim1；Nae-Un Kang1；Dongwoo Sohn3；Young-Sam Cho4,5

Abstract

Abstract: Achieving exact printing fidelity in polymer-based bone regeneration scaffolds through additive manufacturing, particularly those of dispensing-type, remains a significant challenge. During fabrication, scaffolds often deviate from the intended design geometry, which can negatively affect their performance. Additionally, achieving mechanical properties similar to natural bone in scaffolds remains challenging. Therefore, this study introduces the Hybrid Modified CubicHoneycomb Plate (hybrid MCHP) structure to improve printing fidelity and mechanical properties over previous bone regeneration scaffolds through innovative geometry design. This hybrid MCHP scaffold was inspired by cubic honeycomb and plate-lattice structures due to their excellent mechanical performance and well-optimized geometry, which ensure optimal printability. The effective elastic stiffness of the proposed structure and control group was predicted using a numerical Asymptotic Expansion Homogenization (AEH) model. Bone regeneration scaffolds were fabricated using Polycaprolactone (PCL) and a 3D printer with a Precision Extrusion Deposition (PED) system. Printing fidelity in manufactured scaffolds was then evaluated, resulting in a printing fidelity of 97.93±1.1% for the hybrid MCHP-structure scaffold (compared to 82.31± 3.6% and 92.00 ±2.5% in the case of Kagome-structure and modified honeycomb (MHC)-structure scaffolds, which are the control groups). Mechanical testing of the hybrid MCHP-structure scaffold using a Universal Testing Machine (UTM) depicted similarity with 91.1% of the numerical estimated effective elastic stiffness (compared to 82.8% and 79.0% in the case of Kagome-structure and MHC-structure scaffolds, which serve as the control groups). The biological potential of the scaffolds was evaluated through in vitro studies using MC3T3-E1 pre-osteoblasts. The CCK-8 assay showed significantly enhanced cell viability and proliferation on the hybrid MCHP scaffold at all time points (days 1, 7, and 14), consistently outperforming the Kagome and MHC scaffolds. Additionally, immunofluorescence staining analysis revealed abundant focal adhesions and uniform nuclear distribution, highlighting the superior cytocompatibility and effective support for cellular activity of the hybrid MCHP scaffold.

Key words: Printing fidelity')">Printing fidelity, Hybrid modified cubic-honeycomb plate structure, Scaffold, Bone regeneration

Rigoberto Lopez Reyes, Min-Soo Ghim, Eun Chae Kim, Nae-Un Kang, D. Sohn, Young-Sam Cho. Hybrid Modified Cubic-Honeycomb-Plate Structure: A Novel Bone Regeneration Scaffold with Enhanced Mechanical Stiffness Achieved Through High Printing Fidelity

[J].Journal of Bionic Engineering, 2025, 22(4): 1881-1909.

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”. Please open it by linking:http://jbe.jlu.edu.cn/EN/abstract/abstract1608.shtml" name="neirong"> Printing fidelity；Hybrid modified cubic-honeycomb plate structure；Scaffold；Bone regeneration

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URL: http://jbe.jlu.edu.cn/EN/10.1007/s42235-025-00733-5

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