A Computationally-Designed 3D Printed Segmental Defect Implant for Optimized Mechanobiologic Performance Under Simulated Physiological Loads Using Sheep Model

Ali Kiapour; Khashayar  Khazaee; Mitchell  Greenberg; Matias  Alonso; Mohammadjavad Einafshar; Santiago Lozano-Calderon; Thomas P. Schaer

A Computationally-Designed 3D Printed Segmental Defect Implant for Optimized Mechanobiologic Performance Under Simulated Physiological Loads Using Sheep Model

Ali Kiapour, Khashayar Khazaee, Mitchell Greenberg, Matias Alonso, Mohammadjavad Einafshar, Santiago Lozano-Calderon, Thomas P. Schaer

Research output: Contribution to conference without publisher/journal › Conference abstract for conference › Research › peer-review

Abstract

While intramedullary nailing fixation is the preferred treatment for femoral shaft fractures, a nonunion can still develop. Aseptic nonunion is a serious complication that may arise following the treatment of long bone fractures with intramedullary nailing, with an incidence rate of up to 12.5% in the femur and tibia. Stress and load shielding due to the use of solid nails and high-stiffness fixation constructs can contribute to nonfusion due to bone loss. Studies have shown that mechanical stiffness and properties of the fixation implants can affect the osteointegration and fusion rates.This work demonstrates the biomechanical assessment of computationally optimized implants to be used in animal study for clinical assessment of the fusion

Original language	English
Publication date	11 Feb 2025
Publication status	Published - 11 Feb 2025
Event	Orthopedic Research Society (ORS) Annual Meeting : ORS 2025 - Phoenix, Arizona, Phoenix, United States Duration: 7 Feb 2025 → 11 Mar 2025 https://www.ors.org/2025annualmeeting/

Conference

Conference	Orthopedic Research Society (ORS) Annual Meeting
Location	Phoenix, Arizona
Country/Territory	United States
City	Phoenix
Period	07/02/2025 → 11/03/2025
Internet address	https://www.ors.org/2025annualmeeting/

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Kiapour, A., Khazaee, K., Greenberg, M., Alonso, M., Einafshar, M., Lozano-Calderon, S., & Schaer, T. P. (2025). A Computationally-Designed 3D Printed Segmental Defect Implant for Optimized Mechanobiologic Performance Under Simulated Physiological Loads Using Sheep Model. Abstract from Orthopedic Research Society (ORS) Annual Meeting , Phoenix, Arizona, United States.

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title = "A Computationally-Designed 3D Printed Segmental Defect Implant for Optimized Mechanobiologic Performance Under Simulated Physiological Loads Using Sheep Model",

abstract = "While intramedullary nailing fixation is the preferred treatment for femoral shaft fractures, a nonunion can still develop. Aseptic nonunion is a serious complication that may arise following the treatment of long bone fractures with intramedullary nailing, with an incidence rate of up to 12.5% in the femur and tibia. Stress and load shielding due to the use of solid nails and high-stiffness fixation constructs can contribute to nonfusion due to bone loss. Studies have shown that mechanical stiffness and properties of the fixation implants can affect the osteointegration and fusion rates.This work demonstrates the biomechanical assessment of computationally optimized implants to be used in animal study for clinical assessment of the fusion",

author = "Ali Kiapour and Khashayar Khazaee and Mitchell Greenberg and Matias Alonso and Mohammadjavad Einafshar and Santiago Lozano-Calderon and Schaer, {Thomas P.}",

year = "2025",

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day = "11",

language = "English",

note = "Orthopedic Research Society (ORS) Annual Meeting : ORS 2025, ORS ; Conference date: 07-02-2025 Through 11-03-2025",

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A Computationally-Designed 3D Printed Segmental Defect Implant for Optimized Mechanobiologic Performance Under Simulated Physiological Loads Using Sheep Model. / Kiapour, Ali; Khazaee, Khashayar ; Greenberg, Mitchell et al.
2025. Abstract from Orthopedic Research Society (ORS) Annual Meeting , Phoenix, Arizona, United States.

Research output: Contribution to conference without publisher/journal › Conference abstract for conference › Research › peer-review

TY - ABST

T1 - A Computationally-Designed 3D Printed Segmental Defect Implant for Optimized Mechanobiologic Performance Under Simulated Physiological Loads Using Sheep Model

AU - Kiapour, Ali

AU - Khazaee, Khashayar

AU - Greenberg, Mitchell

AU - Alonso, Matias

AU - Einafshar, Mohammadjavad

AU - Lozano-Calderon, Santiago

AU - Schaer, Thomas P.

PY - 2025/2/11

Y1 - 2025/2/11

N2 - While intramedullary nailing fixation is the preferred treatment for femoral shaft fractures, a nonunion can still develop. Aseptic nonunion is a serious complication that may arise following the treatment of long bone fractures with intramedullary nailing, with an incidence rate of up to 12.5% in the femur and tibia. Stress and load shielding due to the use of solid nails and high-stiffness fixation constructs can contribute to nonfusion due to bone loss. Studies have shown that mechanical stiffness and properties of the fixation implants can affect the osteointegration and fusion rates.This work demonstrates the biomechanical assessment of computationally optimized implants to be used in animal study for clinical assessment of the fusion

AB - While intramedullary nailing fixation is the preferred treatment for femoral shaft fractures, a nonunion can still develop. Aseptic nonunion is a serious complication that may arise following the treatment of long bone fractures with intramedullary nailing, with an incidence rate of up to 12.5% in the femur and tibia. Stress and load shielding due to the use of solid nails and high-stiffness fixation constructs can contribute to nonfusion due to bone loss. Studies have shown that mechanical stiffness and properties of the fixation implants can affect the osteointegration and fusion rates.This work demonstrates the biomechanical assessment of computationally optimized implants to be used in animal study for clinical assessment of the fusion

M3 - Conference abstract for conference

T2 - Orthopedic Research Society (ORS) Annual Meeting

Y2 - 7 February 2025 through 11 March 2025

ER -

A Computationally-Designed 3D Printed Segmental Defect Implant for Optimized Mechanobiologic Performance Under Simulated Physiological Loads Using Sheep Model

Abstract

Conference

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