Bilayer Implants

Schagemann, Jan C.; Rudert, Nicola; Taylor, Michelle E.; Sim, Sotcheadt; Quenneville, É.; Garon, M.; Klinger, M.; Buschmann, Michael D.; Mittelstaedt, Hagen

doi:10.1177/1947603515623992

Cited by 14 publications

(2 citation statements)

References 73 publications

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“…It has recently been shown that electromechanical assessment of cartilage quality after implantation of bilayer constructs was comparable with evaluation by conventional destructive methods in an in vivo sheep model. 15 Similarly, measurement of cartilage electromechanical properties during routine arthroscopic procedures can help to evaluate the tissue quality before major macroscopic lesions appear. Advantages and limitations of the described technique are discussed in Table 2 .…”

Section: Discussionmentioning

confidence: 99%

Quantitative Arthroscopic Assessment of Articular Cartilage Quality by Means of Cartilage Electromechanical Properties

Mickevičius

Mačiulaitis

Ūsas

et al. 2018

Arthroscopy Techniques

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Arthroscopic surgery has grown rapidly in recent decades. Despite accurately diagnosed clinical cases, the previous pain is retained in some patients after the operation, even though no visible chondral lesions are found during the procedure. A minimally invasive arthroscopic method of measuring articular cartilage electromechanical properties enables rapid and reliable intraoperative articular cartilage quality evaluation.

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Section: Discussionmentioning

confidence: 99%

Quantitative Arthroscopic Assessment of Articular Cartilage Quality by Means of Cartilage Electromechanical Properties

Mickevičius

Mačiulaitis

Ūsas

et al. 2018

Arthroscopy Techniques

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“…Hydrogels are categorized as natural and synthetic and can be modulated with cell-free or cell-laden scaffolds. Some of the cell-free scaffolds have been presented with the use of bacterial nano-cellulose [ 102 ], polyethylene glycol (PEG) in combination with HA [ 103 ], collagen-hydroxyapatite hybrids [ 104 ], aragonite-hyaluronate membranes [ 105 ], acrylamide (AAm) hydrogels [ 106 ], alginate (Alg)/chitosan compounds, agarose/polyglycolic acids (PGA) [ 107 ], and porous polycaprolactone (PCL) [ 108 ]. The mentioned scaffolds were used clinically; however, after clinical follow-up in the longer term, they were rejected due to the lack of strength and durability.…”

Section: Tissue Engineering Of Articular Cartilagementioning

confidence: 99%

Articular and Artificial Cartilage, Characteristics, Properties and Testing Approaches—A Review

2021

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The design and manufacture of artificial tissue for knee joints have been highlighted recently among researchers which necessitates an apt approach for its assessment. Even though most re-searches have focused on specific mechanical or tribological tests, other aspects have remained underexplored. In this review, elemental keys for design and testing artificial cartilage are dis-cussed and advanced methods addressed. Articular cartilage structure, its compositions in load-bearing and tribological properties of hydrogels, mechanical properties, test approaches and wear mechanisms are discussed. Bilayer hydrogels as a niche in tissue artificialization are presented, and recent gaps are assessed.

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Electromechanical probe and automated indentation maps are sensitive techniques in assessing early degenerated human articular cartilage

Sim

Chevrier

Garon

et al. 2016

Journal Orthopaedic Research

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Recent advances in the development of new drugs to halt or even reverse the progression of Osteoarthritis at an early-stage requires new tools to detect early degeneration of articular cartilage. We investigated the ability of an electromechanical probe and an automated indentation technique to characterize entire human articular surfaces for rapid non-destructive discrimination between early degenerated and healthy articular cartilage. Human cadaveric asymptomatic articular surfaces (four pairs of distal femurs and four pairs of tibial plateaus) were used. They were assessed ex vivo: macroscopically, electromechanically, (maps of the electromechanical quantitative parameter, QP, reflecting streaming potentials), mechanically (maps of the instantaneous modulus, IM), and through cartilage thickness. Osteochondral cores were also harvested from healthy and degenerated regions for histological assessment, biochemical analyses, and unconfined compression tests. The macroscopic visual assessment delimited three distinct regions on each articular surface: Region I was macroscopically degenerated, region II was macroscopically normal but adjacent to regions I and III was the remaining normal articular surface. Thus, each extracted core was assigned to one of the three regions. A mixed effect model revealed that only the QP (p < 0.0001) and IM (p < 0.0001) were able to statistically discriminate the three regions. Effect size was higher for QP and IM than other assessments, indicating greater sensitivity to distinguish early degeneration of cartilage. When considering the mapping feature of the QP and IM techniques, it also revealed bilateral symmetry in a moderately similar distribution pattern between bilateral joints. © 2016 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 35:858-867, 2017.

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Bilayer Implants

Cited by 14 publications

References 73 publications

Quantitative Arthroscopic Assessment of Articular Cartilage Quality by Means of Cartilage Electromechanical Properties

Quantitative Arthroscopic Assessment of Articular Cartilage Quality by Means of Cartilage Electromechanical Properties

Articular and Artificial Cartilage, Characteristics, Properties and Testing Approaches—A Review

Electromechanical probe and automated indentation maps are sensitive techniques in assessing early degenerated human articular cartilage

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