Revealing Detailed Cartilage Function Through Nanoparticle Diffusion Imaging: A Computed Tomography & Finite Element Study.

The ability of articular cartilage to withstand significant mechanical stresses during activities, such as walking or running, relies on its distinctive structure. Integrating detailed tissue properties into subject-specific biomechanical models is challenging due to the complexity of analyzing these characteristics. This limitation compromises the accuracy of models in replicating cartilage function and impacts predictive capabilities. To address this, methods revealing cartilage function at the constituent-specific level are essential. In this study, we demonstrated that computational modeling derived individual constituent-specific biomechanical properties could be predicted by a novel nanoparticle contrast-enhanced computer tomography (CECT) method. We imaged articular cartilage samples collected from the equine stifle joint (n = 60) using contrast-enhanced micro-computed tomography (µCECT) to determine contrast agents' intake within the samples, and compared those to cartilage functional properties, derived from a fibril-reinforced poroelastic finite element model. Two distinct imaging techniques were investigated: conventional energy-integrating µCECT employing a cationic tantalum oxide nanoparticle (Ta2O5-cNP) contrast agent and novel photon-counting µCECT utilizing a dual-contrast agent, comprising Ta2O5-cNP and neutral iodixanol. The results demonstrate the capacity to evaluate fibrillar and non-fibrillar functionality of cartilage, along with permeability-affected fluid flow in cartilage. This finding indicates the feasibility of incorporating these specific functional properties into biomechanical computational models, holding potential for personalized approaches to cartilage diagnostics and treatment.

Composition, architecture and biomechanical properties of articular cartilage in differently loaded areas of the equine stifle.

BACKGROUND: Strategies for articular cartilage repair need to take into account topographical differences in tissue composition and architecture to achieve durable functional outcome. These have not yet been investigated in the equine stifle. OBJECTIVES: To analyse the biochemical composition and architecture of three differently loaded areas of the equine stifle. We hypothesise that site differences correlate with the biomechanical characteristics of the cartilage. STUDY DESIGN: Ex vivo study. METHODS: Thirty osteochondral plugs per location were harvested from the lateral trochlear ridge (LTR), the distal intertrochlear groove (DITG) and the medial femoral condyle (MFC). These underwent biochemical, biomechanical and structural analysis. A linear mixed model with location as a fixed factor and horse as a random factor was applied, followed by pair-wise comparisons of estimated means with false discovery rate correction, to test for differences between locations. Correlations between biochemical and biomechanical parameters were tested using Spearman's correlation coefficient. RESULTS: Glycosaminoglycan content was different between all sites (estimated mean [95% confidence interval (CI)] for LTR 75.4 [64.5, 88.2], for intercondylar notch (ICN) 37.3 [31.9, 43.6], for MFC 93.7 [80.1109.6] µg/mg dry weight), as were equilibrium modulus (LTR2.20 [1.96, 2.46], ICN0.48 [0.37, 0.6], MFC1.36 [1.17, 1.56] MPa), dynamic modulus (LTR7.33 [6.54, 8.17], ICN4.38 [3.77, 5.03], MFC5.62 [4.93, 6.36] MPa) and viscosity (LTR7.49 [6.76, 8.26], ICN16.99 [15.88, 18.14], MFC8.7 [7.91,9.5]°). The two weightbearing areas (LTR and MCF) and the non-weightbearing area (ICN) differed in collagen content (LTR 139 [127, 152], ICN176[162, 191], MFC 127[115, 139] µg/mg dry weight), parallelism index and angle of collagen fibres. The strongest correlations were between proteoglycan content and equilibrium modulus (r: 0.642; p: 0.001), dynamic modulus (r: 0.554; p < 0.001) and phase shift (r: -0.675; p < 0.001), and between collagen orientation angle and equilibrium modulus (r: -0.612; p < 0.001), dynamic modulus (r: -0.424; p < 0.001) and phase shift (r: 0.609; p < 0.001). MAIN LIMITATIONS: Only a single sample per location was analysed. CONCLUSIONS: There were significant differences in cartilage biochemical composition, biomechanics and architecture between the three differently loaded sites. The biochemical and structural composition correlated with the mechanical characteristics. These differences need to be acknowledged by designing cartilage repair strategies.

INTRODUCTION/CONTEXTE: Les stratégies de réparation du cartilage articulaire doivent tenir compte des différences topographiques en ce qui a trait à la composition et l'architecture des tissues, afin d'obtenir un résultat durable et fonctionnel. Celles­ci n'ont pas encore été étudiées chez le grasset équin. OBJECTIFS: Analyser la composition biochimique et l'architecture de trois régions du grasset portant une quantité de poids différente. Nous émettons l'hypothèse que les différences entre régions seront corrélées aux caractéristiques biomécaniques du cartilage. TYPE D'ÉTUDE: Étude ex vivo. MÉTHODES: Trente échantillons ostéochondraux par site ont été récoltés à partir de la lèvre latérale de la trochlée fémorale (LTR), le sillon intertrochléaire distal (DITG) et le condyle fémoral médial (MFC). Ceux­ci ont été soumis à des tests biochimiques, biomécaniques et une analyse structurelle. Un modèle linéaire mixte avec localisation comme facteur fixe et cheval comme facteur randomisé a été appliqué. Puis, ont suivi des comparaisons par paires de moyennes estimées avec contrôle du taux de fausses découvertes, pour tester les différences entre les divers sites. Les corrélations entre les paramètres biochimiques et biomécaniques ont été testé par le coefficient de corrélation Spearman. RÉSULTATS: Le contenu en glycosaminoglycans était différent à chacun des sites (moyenne estimée [95% CI] pour LTR 75.4 [64.5, 88.2], pour ICN 37.3 [31.9, 43.6], pour MFC 93.7[80.1109.6]µg/mg matière sèche), tout comme le module d'équilibre (LTR2.20 [1.96, 2.46], ICN0.48 [0.37, 0.6], MFC1.36 [1.17, 1.56] MPa), le module dynamique (LTR7.33 [6.54, 8.17], ICN4.38[3.77, 5.03], MFC5.62[4.93, 6.36] MPa) et la viscosité (LTR7.49[6.76, 8.26], ICN16.99 [15.88, 18.14], MFC8.7 [7.91, 9.5]°). Les deux régions portant du poids (LTR et MFC) et la région ne supportant pas de poids (ICN) diffèrent par rapport à leur contenu en collagène (LTR 139 [127152], ICN176 [162191], MFC 127 [115139] µg/mg matière sèche), à l'index de parallélisle et à l'angle des fibres de collagène. Les corrélations les plus fortes étaient entre le contenu en protéoglycans et le module d'équilibre (r: 0.642; p: 0.001), le module dynamique (r: 0.554; p < 0.001) et le changement de phase (r:−0.675; p < 0.001), et entre l'angle d'orientation du collagène et le module d'équilibre (r:−0.612; p < 0.001), le module dynamique (r:−0.424; p < 0.001) et le changement de phase (r: 0.609;p:<0.001). LIMITES PRINCIPALES: Seulement un échantillon par site a été soumis aux analyses. CONCLUSIONS: Il existe des différences significatives dans la composition biochimique, biomécanique et l'architecture du cartilage entre les trois sites échantillonnés. La composition biochimique et structurelle corrèle avec les caractéristiques mécaniques. Ces différences doivent être prises en compte lors de la création de stratégies de réparation du cartilage.

Cationic tantalum oxide nanoparticle contrast agent for micro computed tomography reveals articular cartilage proteoglycan distribution and collagen architecture alterations.

OBJECTIVE: Cationic tantalum oxide nanoparticles (Ta2O5-cNPs), as a newly introduced contrast agent for computed tomography of cartilage, offer quantitative evaluation of proteoglycan (PG) content and biomechanical properties. However, knowledge on the depth-wise impact of cartilage constituents on nanoparticle diffusion, particularly the influence of the collagen network, is lacking. In this study, we aim to establish the depth-dependent relationship between Ta2O5-cNP diffusion and cartilage constituents (PG content, collagen content and network architecture). METHODS: Osteochondral samples (n = 30) were harvested from healthy equine stifle joints (N = 15) and the diffusion of 2.55 nm diameter cationic Ta2O5-cNPs into the cartilage was followed with micro computed tomography (µCT) imaging for up to 96 hours. The diffusion-related parameters, Ta2O5-cNP maximum partition (Pmax) and diffusion time constant, were compared against biomechanical and depth-wise structural properties. Biomechanics were assessed using stress-relaxation and sinusoidal loading protocols, whereas PG content, collagen content and collagen network architecture were determined using digital densitometry, Fourier-transform infrared spectroscopy and polarized light microscopy, respectively. RESULTS: The Pmax correlates with the depth-wise distribution of PGs (bulk Spearman's ρ = 0.87, p < 0.001). More open collagen network architecture at the superficial zone enhances intake of Ta2O5-cNPs, but collagen content overall decreases the intake. The Pmax values correlate with the equilibrium modulus (ρ = 0.80, p < 0.001) of articular cartilage. CONCLUSION: This study establishes the feasibility of Ta2O5-cNPs for the precise and comprehensive identification of biomechanical and structural changes in articular cartilage via contrast-enhanced µCT.

Reporting of anaesthesia and pain management in preclinical large animal models of articular cartilage repair - A long way to go.

Animal models continue to be used to investigate cartilage repair strategies. Adequate anaesthesia and pain management are essential in order to guarantee acceptable animal welfare as well as reproducible experimental results. This systematic review evaluates reporting of anaesthesia and pain management in surgical large animal models (horse, pig, dog, goat and sheep) of (osteo)chondral repair. Manuscripts published between 2015 and 2020 were included after a comprehensive search strategy. Data were evaluated using descriptive statistics and qualitative review. Out of 223 eligible studies, 220 studies contained incomplete information on anaesthetic and pain management. Pre-, intra- and post-operative analgesia were not mentioned in 68%, 94%, and 64% of manuscripts respectively. A total of 176 studies reported that animals underwent general anaesthesia during surgery. Surprisingly, 30% of these articles did not provide any detail on anaesthetic management, while 37% reported using inhalant, hypnotic or sedative drugs only, without mention of analgesics. Pain monitoring was not reported in 87% of manuscripts. The vast majority of preclinical large animal studies on cartilage repair did not meet veterinary clinical standards for anaesthesia and analgesia, and failed to report according to the ARRIVE international guidelines. In light of serious welfare, ethical and translational validity concerns, improvement is urgently needed.

Agenesis and Dysgenesis of the Navicular Bone as Cause of Lameness and Malalignment in Two Foals.

A three-week-old warmblood colt was referred for a two-week history of lameness on the left thoracic limb, and a two-month-old Quarter Horse-mix filly was referred for malaligned pelvic limbs since birth. The foals were diagnosed with agenesis and dysgenesis of the navicular bone, respectively. In this report, we present clinical signs, diagnostics, and postmortem workup of the two cases.

Surgical osteochondral defect repair in the horse-a matter of form or function?

Focal cartilaginous and osteochondral lesions can have traumatic or chondropathic degenerative origin. The fibrocartilaginous repair tissue that forms naturally, eventually undergoes fibrillation and degeneration leading to further disruption of joint homeostasis. Both types of lesion will therefore eventually lead to activity-related pain, swelling and decreased mobility and will frequently progress to osteoarthritis. Most attempts at realising cartilage regeneration have so far resulted in cartilage repair (and not regeneration). The aim of this article was to review experimental research on surgical cartilage restoration techniques performed so far in equine models. Currently available surgical options for treatment of osteochondral lesions in the horse are summarised. The experimental validity of equine experimental models is addressed and finally possible avenues for further research are discussed.

Non-genomic action of beclomethasone dipropionate on bronchoconstriction caused by leukotriene C4 in precision cut lung slices in the horse.

BACKGROUND: Glucocorticoids have been proven to be effective in the therapy of recurrent airway obstruction (RAO) in horses via systemic as well as local (inhalative) administration. Elective analysis of the effects of this drug on bronchoconstriction in viable lung tissue offers an insight into the mechanism of action of the inflammatory cascade occurring during RAO which is still unclear. The mechanism of action of steroids in treatment of RAO is thought to be induced through classical genomic pathways. We aimed at electively studying the effects of the glucocorticoid beclomethasone dipropionate on equine precision-cut lung slices (PCLS).PCLS were used to analyze ex-vivo effects of beclomethasone on inhibiting bronchoconstriction in the horse. The inhibiting effect was measured through instillation of a known mediator of inflammation and bronchoconstriction, leukotriene C4. For this, the accessory lobes of 13 horses subjected to euthanasia for reasons unrelated to the respiratory apparatus were used to obtain viable lung slices. RESULTS: After 30 minutes of PCLS incubation, beclomethasone showed to significantly inhibit the contraction of the bronchioles after instillation with leukotriene C4. The EC50 values of the two contraction curves (LTC4 with and without BDP) differed significantly from each other (p = 0.002). The possibility of a non-genomic rapid mechanism of action seems likely since transcriptional activities require a longer lag period. CONCLUSIONS: In human neuroendocrinology, high levels of glucocorticoids have been proven to function via a non-genomic mechanism of membrane receptors. The concentration of beclomethasone used on the lung slices in our study can be considered as high. This allows speculation about similar rapid non-genomic mechanisms of high-dosage inhaled glucocorticoids in the lower airways of horses. However, further assessment on a molecular basis is needed to confirm this.

DNA recovered and sequenced from an almost 7000 y-old Neolithic polypore, Daedaleopsis tricolor.

Ten fragments of a wood-inhabiting polypore were found in the early Neolithic village of 'La Marmotta' (Anguillara Sabazia, Rome), formerly located on the shore of the Bracciano Lake. Five of these were found in three different huts, and two outside near other structures. Some fragments of the partly degraded specimens were used for DNA sequencing in order to the identity of the fungus, which proved to be Daedaleopsis tricolor. Pharmacological aspects of this and other previously discovered prehistoric polypores are also noted.