C. Krais scite author profile

C. Krais

2Publications

5Citation Statements Received

36Citation Statements Given

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Hochschule Ulm

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<p>The MOVE-C Cervical Artificial Disc – Design, Materials, Mechanical Safety</p>

Kienle¹,

Graf²,

Krais³

et al. 2020

MDER

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Purpose: There are various cervical disc prostheses on the market today. They can be subdivided into implants with a ball-and-socket design and implants with a flexible core, which is captured between the implant endplates and sealed using various sheaths. Implants with an articulating surface are mostly metal-on-metal or metal-on-UHMWPE designs and, thus, do not allow for axial damping. The aim of this study is to provide mechanical safety and performance data of the MOVE-C cervical disc prosthesis which combines both an articulating surface and a flexible core. Materials and Methods: MOVE-C consists of a cranial and caudal metal plate made of TiAl6V4. The cranial plate is TiNbN coated on its articulating surface. The caudal plate has a fixed polycarbonate-urethane (PCU) core. The TiNbN coating is meant to optimize the wear behavior of the titanium endplate, whereas the PCU core is meant to allow for a reversible axial deformation, a pre-defined neutral zone and a progressive load-deformation curve in all planes. Results: Various standard testing procedures (for example, ISO 18192-1 and ASTM F2364) and non-standard mechanical tests were carried out to prove the implant's mechanical safety. Due to the new implant design, wear and creep testing was deemed most important. The wear rate for the PCU was in maximum 1.54 mg per million cycles. This value was within the range of the UHMWPE wear rates reported for other cervical disc prostheses (0.53 to 2.59 mg/million cycles). Also in the creep-relaxation test, a qualitatively physiological behavior was shown with a certain amount of remaining deformation but no failure. Conclusion: The mechanical safety of the MOVE-C cervical disc prosthesis was shown to be comparable to other cervical disc prostheses. Since PCU wear particles were elsewhere shown to be less bioactive than cross-linked UHMWPE particles, wear-related failure in vivo may be less frequent compared to other prostheses. This, however, will have to be shown in further studies.

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Development of a Patient-Specific Carbon-Prosthesis to Support Sporting Activities

Dürr

Krais

Peschmann

et al. 2012

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This paper describes the development of a forefootprosthesis for a patient with an amputation to the Lisfranc level with the intention to enable sportive activities like endurance run or Nordic walking. The prosthesis is made of carbon fibre and has a customized anatomical design. The load transmission starts at the caput tibia and lead it over the stem to the area of the toes. Therefore the carbon-prosthesis was integrated into a running shoe with an individual stump-bed. The functional properties of the prosthesis were initially evaluated by a gait analysis.

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C. Krais

<p>The MOVE-C Cervical Artificial Disc – Design, Materials, Mechanical Safety</p>

Development of a Patient-Specific Carbon-Prosthesis to Support Sporting Activities

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