TY - JOUR
T1 - Determination of the internal loads experienced by proximal phalanx fracture fixations during rehabilitation exercises
AU - Schwarzenberg, Peter
AU - Colding-Rasmussen, Thomas
AU - Hutchinson, Daniel J
AU - San Jacinto Garcia, Jorge
AU - Granskog, Viktor
AU - Mørk Petersen, Michael
AU - Pastor, Tatjana
AU - Weis, Tine
AU - Malkoch, Michael
AU - Nai En Tierp-Wong, Christian
AU - Varga, Peter
N1 - Copyright © 2024 Schwarzenberg, Colding-Rasmussen, Hutchinson, San Jacinto Garcia, Granskog, Mørk Petersen, Pastor, Weis, Malkoch, Nai En Tierp-Wong and Varga.
PY - 2024
Y1 - 2024
N2 - Phalangeal fractures are common, particularly in younger patients, leading to a large economic burden due to higher incident rates among patients of working age. In traumatic cases where the fracture may be unstable, plate fixation has grown in popularity due to its greater construct rigidity. However, these metal plates have increased reoperation rates due to inflammation of the surrounding soft tissue. To overcome these challenges, a novel osteosynthesis platform, AdhFix, has been developed. This method uses a light-curable polymer that can be shaped in situ around traditional metal screws to create a plate-like structure that has been shown to not induce soft tissue adhesions. However, to effectively evaluate any novel osteosynthesis device, the biomechanical environment must first be understood. In this study, the internal loads in a phalangeal plate osteosynthesis were measured under simulated rehabilitation exercises. In a human hand cadaver study, a plastic plate with known biomechanical properties was used to fix a 3 mm osteotomy and each finger was fully flexed to mimic traditional rehabilitation exercises. The displacements of the bone fragments were tracked with a stereographic camera system and coupled with specimen specific finite element (FE) models to calculate the internal loads in the osteosynthesis. Following this, AdhFix patches were created and monotonically tested under similar conditions to determine survival of the novel technique. The internal bending moment in the osteosynthesis was 6.78 ± 1.62 Nmm and none of the AdhFix patches failed under the monotonic rehabilitation exercises. This study demonstrates a method to calculate the internal loads on an osteosynthesis device during non-load bearing exercises and that the novel AdhFix solution did not fail under traditional rehabilitation protocols in this controlled setting. Further studies are required prior to clinical application.
AB - Phalangeal fractures are common, particularly in younger patients, leading to a large economic burden due to higher incident rates among patients of working age. In traumatic cases where the fracture may be unstable, plate fixation has grown in popularity due to its greater construct rigidity. However, these metal plates have increased reoperation rates due to inflammation of the surrounding soft tissue. To overcome these challenges, a novel osteosynthesis platform, AdhFix, has been developed. This method uses a light-curable polymer that can be shaped in situ around traditional metal screws to create a plate-like structure that has been shown to not induce soft tissue adhesions. However, to effectively evaluate any novel osteosynthesis device, the biomechanical environment must first be understood. In this study, the internal loads in a phalangeal plate osteosynthesis were measured under simulated rehabilitation exercises. In a human hand cadaver study, a plastic plate with known biomechanical properties was used to fix a 3 mm osteotomy and each finger was fully flexed to mimic traditional rehabilitation exercises. The displacements of the bone fragments were tracked with a stereographic camera system and coupled with specimen specific finite element (FE) models to calculate the internal loads in the osteosynthesis. Following this, AdhFix patches were created and monotonically tested under similar conditions to determine survival of the novel technique. The internal bending moment in the osteosynthesis was 6.78 ± 1.62 Nmm and none of the AdhFix patches failed under the monotonic rehabilitation exercises. This study demonstrates a method to calculate the internal loads on an osteosynthesis device during non-load bearing exercises and that the novel AdhFix solution did not fail under traditional rehabilitation protocols in this controlled setting. Further studies are required prior to clinical application.
KW - CT derived models
KW - customizable osteosythesis
KW - finite element modeling
KW - non-contact measurement
KW - patient-specific treatment
UR - http://www.scopus.com/inward/record.url?scp=85203878492&partnerID=8YFLogxK
U2 - 10.3389/fbioe.2024.1388399
DO - 10.3389/fbioe.2024.1388399
M3 - Journal article
C2 - 39286344
SN - 2296-4185
VL - 12
JO - Frontiers in bioengineering and biotechnology
JF - Frontiers in bioengineering and biotechnology
M1 - 1388399
ER -