关节软骨退变磁共振3D-FS-FSPGR 序列成像与病理对照研究

目的：评价三维脂肪抑制快速扰相梯度回波（3D-FS-FSPGR）序列对膝关节软骨退变的诊断价值。方法对30例因骨关节炎行全膝关节置换患者的32侧膝关节术前行3D-FS-FSPGR 序列 MRI 成像,按照 Recht 标准对 MRI 图像上的软骨病变程度进行分级。手术医师术中根据 MRI 图像上提示的软骨病变区位置,钻取软骨和软骨下骨组织,获取0～Ⅲ度病变软骨标本各15个,标本切片行 HE 染色,按照 Collins 分级标准进行病理分级,并与 MRI 分级对照分析;甲苯胺蓝和Ⅱ型胶原免疫组化染色,分别观察软骨内蛋白多糖（PG）和Ⅱ型胶原纤维,分析两者的变化,及其与 MRI 图像软骨信号变化的关系。结果病理检查结果：0级16个,Ⅰ级13个,Ⅱ级15个,Ⅲ级16个。以病理分级为标准,3D FS-FSPGR 序列诊断的灵敏度为93．2％,特异度为75％,准确率为88．3％,kappa 值为0．71。关节软骨病理显示：MRI 分级越高软骨之间病理变化越明显;随病变加重,软骨基质破坏愈加严重,PG 随着软骨病变加重,染色深度呈递减关系;Ⅱ型胶原随着软骨病变加重,染色先加深后变浅。结论3D-FS-FSPGR 序列 MRI 能够准确的显示关节软骨病变,反映了软骨病理和生化的变化,具备发现关节软骨早期病变的能力。     

Subchondral bone fragility with meniscal tear accelerates and parathyroid hormone decelerates articular cartilage degeneration in rat osteoarthritis model

The aims of this study were to investigate the influence of subchondral bone fragility (SBF) on the progression of the knee osteoarthritis by using a novel rat model, and to examine the preventive effect of parathyroid hormone (PTH) on cartilage degeneration. First, 40 rats were assigned to the following four groups: Sham, SBF, Medial meniscal tear (MMT), and MMT + SBF groups. In SBF and MMT + SBF groups, we induced SBF by microdrilling the subchondral bone. Second, 10 additional rats were randomly assigned to the following two groups: MMT + SBF + saline and MMT + SBF + PTH groups. Osteoarthritic changes in the articular cartilage and subchondral bone were evaluated using safranin‐O/fast green staining, matrix metalloproteinase‐13 (MMP‐13), and type X collagen immunohistochemistry, toluidine blue staining, and micro‐CT scanning. The combination of SBF and meniscal tear increased the number of mast cells in the subchondral bone, and led to the abnormal subchondral bone microarchitecture, such as abnormally decreased trabecular number and increased trabecular thickness, compared with meniscal tear alone. Moreover, SBF with meniscal tear enhanced articular cartilage degeneration and increased the expression of MMP‐13 and type X collagen, compared with meniscal tear alone. The administration of PTH decreased the number of mast cells in the subchondral bone and improved the microstructural parameters of the subchondral bone, and delayed the progression of articular cartilage degeneration. These results suggest that SBF is one of the factors underlying the osteoarthritis development, especially in knees with traumatic osteoarthritis, and that the administration of PTH is a potential therapeutic treatment for preventing OA progression. © 2017 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 36:1959–1968, 2018.

     

降钙素在体内体外实验中对兔关节炎关节软骨退变及软骨下骨骨代谢的影响

[目的]研究降钙素(calcitonin, CT)对骨性关节炎关节软骨退变和软骨下骨骨代谢的影响.[方法]30只3个月龄雌性日本大耳白兔随机分为三组,其中两组行右膝关节前交叉韧带切断术(anterior cruciate ligament transaction,ACLT),分为ACLT+CT组和ACLT+NS组,第3组为Sham组.ACLT+CT给予每日1次皮下注射降钙素5 IU/(kg·d),持续8周,ACLT+NS组给予同样剂量生理盐水.术后8周后处死所有动物.取股骨髁制成切片行MMP-13和Ⅱ型胶原免疫组化染色.取胫骨近端制成硬组织切片行骨形态计量学检测.体外实验中,取兔膝关节软骨,经消化、培养,将第3代软骨细胞分三组:向IL-1β组加入人重组IL-1β(10 ng/ml). IL-1β+CT组加入人重组IL-1β (10 ng/ml)2 d后,再向培养液中加入CT(50 ng/ml).正常组不加任何诱导剂和干扰剂培养.然后行MMP-13、Ⅱ型胶原免疫组化检测和Realtime RT-PCR法检测.[结果]Sham组和ACLT+CT组软骨下骨骨小梁相对体积和厚度等均显著高于ACLT+NS组.Sham组和ACLT+CT组的Ⅱ型胶原的光密度值均显著高于ACLT+NS组,而MMP-13的光密度值显著低于ACLT+NS组(P<0.05).正常组和IL-1β+CT组的Ⅱ型胶原光密度值均显著高于IL-1β组而MMP-13的光密度值都显著低于IL-1β组(P<0.05).在正常组和IL-1β+CT组中Ⅱ型胶原的mRNA含量均显著高于IL-1β组而MMP-13的mRNA含量均显著低于IL-1β组(P<0.05).[结论]降钙素5 IU/(kg·d)皮下注射能够增加ACLT兔膝关节软骨Ⅱ型胶原的分泌和抑制MMP-13的表达,并可能通过调节软骨下骨的骨代谢和微结构来保护关节软骨; CT(50 ng/ml)能增加体外培养的含有IL-1β(10 ng/ml)的软骨细胞中Ⅱ型胶原的含量和抑制MMP-13分泌.     

Binding and localization of recombinant lubricin to articular cartilage surfaces.

Lubricin is a secreted, cytoprotective glycoprotein that contributes to the essential boundary lubrication mechanisms necessary for maintaining low friction levels at articular cartilage surfaces. Diminishment of lubricin function is thereby implicated as an adverse contributing factor in degenerative joint diseases such as osteoarthritis. Lubricin occurs as a soluble component of synovial fluid, and is synthesized and localized in the superficial layer of articular cartilage (and thus has also been described as "superficial zone protein", or SZP); however, defined interactions responsible for lubricin retention at this site are not well characterized. In the current studies, we identified molecular determinants that enable lubricin to effectively bind to articular cartilage surfaces. Efficient and specific binding to the superficial zone was observed for synovial lubricin, as well as for recombinant full-length lubricin and a protein construct comprising the lubricin C-terminal (hemopexin-like) domain (LUB-C, encoded by exons 7-12). A construct representing the N-terminal region of lubricin (LUB-N, encoded by exons 2-5) exhibited no appreciable cartilage-binding ability, but displayed the capacity to dimerize, and thus potentially influence lubricin aggregation. Disulfide bond disruption significantly attenuated recombinant lubricin and LUB-C binding to cartilage surfaces, demonstrating a requirement for protein secondary structure in facilitating the appropriate localization of lubricin at relevant tissue interfaces. These findings help identify additional key attributes contributing to lubricin functionality, which would be expected to be instrumental in maintaining joint homeostasis.     

Intra‐articular delivery of glucosamine for treatment of experimental osteoarthritis created by a medial meniscectomy in a rat model

Glucosamine (GlcN) is a naturally occurring amino‐monosaccharide with putative chondroprotective activity. Optimum responses to GlcN are achieved at concentrations which are impractical with oral dosing. Intra‐articular delivery of a bolus dose of GlcN is one way to overcome these pharmacokinetic obstacles. In this study we report the effects of exposing primary human chondrocytes to a bolus dose of GlcN. We also locally administered GlcN in the context of a meniscal transection model of rat osteoarthritis (OA). The knees of male rats were subjected to medial meniscal transection and developed arthritic changes over 4 weeks. Treatment groups were then given thrice weekly 100 μL injections of 35 μg, 350 μg, 1.8 mg, or 3.5 mg of GlcN dissolved in normal saline. Gross images, modified Mankin scores, and histomorphometric measurements were used as outcome measures. The 350 μg dosage of GlcN had the most significant positive impact on all components of the modified Mankin score. Together, these findings suggest the local delivery of high concentrations of GlcN is well tolerated and can suppress experimental OA through influences on both bone and cartilage. © 2013 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 32:302–309, 2014.     

Three‐dimensional imaging and analysis of human cartilage degeneration using Optical Coherence Tomography

Optical Coherence Tomography (OCT) is an evolving imaging technology allowing non‐destructive imaging of cartilage tissue at near‐histological resolution. This study investigated the diagnostic value of real time 3‐D OCT in comparison to conventional 2‐D OCT in the comprehensive grading of human cartilage degeneration. Fifty‐three human osteochondral samples were obtained from eight total knee arthroplasties. OCT imaging was performed by either obtaining a single two‐dimensional cross‐sectional image (2‐D OCT) or by collecting 100 consecutive parallel 2‐D OCT images to generate a volumetric data set of 8 × 8 mm (3‐D OCT). OCT images were assessed qualitatively according to a modified version of the DJD classification and quantitatively by algorithm‐based evaluation of surface irregularity, tissue homogeneity, and signal attenuation. Samples were graded according to the Outerbridge classification and statistically analyzed by one‐way ANOVA, Kruskal Wallis and Tukey's or Dunn's post‐hoc tests. Overall, the generation of 3‐D volumetric datasets and their multiple reconstructions such as rendering, surface topography, parametric, and cross‐sectional views proved to be of potential diagnostic value. With increasing distance to the mid‐sagittal plane and increasing degeneration, score deviations increased, too. In conclusion, 3‐D imaging of cartilage with image analysis algorithms adds considerable potential diagnostic value to conventional OCT diagnostics. © 2015 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 33:651–659, 2015.     

A rabbit model demonstrates the influence of cartilage thickness on intra‐articular drug delivery and retention within cartilage

For evaluation of new approaches to drug delivery into cartilage, the choice of an animal model is critically important. Since cartilage thickness varies with animal size, different levels of drug uptake, transport and retention should be expected. Simple intra‐articular injection can require very high drug doses to achieve a concentration gradient high enough for drug diffusion into cartilage. New approaches involve nanoparticle delivery of functionalized drugs directly into cartilage; however, diffusion‐binding kinetics proceeds as the square of cartilage thickness. In this study, we demonstrate the necessity of using larger animals for sustained intra‐cartilage delivery and retention, exemplified by intra‐articular injection of Avidin (drug‐carrier) into rabbits and compared to rats in vivo. Penetration and retention of Avidin within cartilage is greatly enhanced by electrostatic interactions. Medial tibial cartilage was the thickest of rabbit cartilages, which generated the longest intra‐cartilage half‐life of Avidin (τ_1/2 = 154 h). In contrast, Avidin half‐life in thinner rat cartilage was 5–6 times shorter (τ_1/2 ～ 29 h). While a weak correlation (R² = 0.43) was found between Avidin half‐lives and rabbit tissue GAG concentrations, this correlation improved dramatically (R² = 0.96) when normalized to the square of cartilage thickness, consistent with the importance of cartilage thickness to evaluation of drug delivery and retention. © 2015 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 33:660–667, 2015.     

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

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.

     

关节软骨缺损修复研究进展

关节软骨是滑膜关节重要的结构和功能单位,一旦关节软骨发生损伤,由于软骨组织本身缺乏血管,缺乏修复损伤和缺损的未分化细胞,软骨细胞包埋于致密的胶原一蛋白多糖基质中,限制了细胞的增殖和迁移能力,所以自身修复能力非常有限,若治疗不及时或不恰当,难以形成正常的关节软骨,因而无法满足正常关节的功能需求,将会导致严重的关节功能障碍。     

膝关节原发性骨关节炎软骨和软骨下骨病理改变的定量研究

目的观察膝关节原发性骨关节炎(osteoarthritis,OA)胫骨平台软骨和软骨下骨病理改变特点,对比内、外侧平台软骨和软骨下骨结构参数,探讨钙化层和软骨下骨在OA发病机制中的作用。方法取2009年10月-2011年5月行人工全膝关节置换术治疗的30例30膝原发性OA患者自愿捐赠的新鲜胫骨平台标本进行实验。其中男11例,女19例;年龄55～78岁,平均65.1岁。病程10～25年,平均16.6年;患膝内翻畸形1～23°,平均9.3°。大体观察胫骨平台后在内、外侧中央负重区取材,常规制备脱钙石蜡切片,行HE和番红O/固绿染色,观察关节软骨退变特点,参照Mankin评分标准评分并分期;观察钙化层及软骨下骨病理改变。应用Image Pro Plus 6.0图像分析软件测量软骨和软骨下骨结构参数,包括软骨全层(total articular cartilage,TAC)厚度、钙化层(articular calcified cartilage,ACC)厚度、ACC/TAC比值、软骨下骨板(subchondral bone plate,SCP)厚度以及骨小梁体积分数(trabecular bone volume,BV/TV)。结果大体观察内侧平台软骨退变较外侧严重,内侧平台软骨Mankin评分为(12.4±1.1)分,显著高于外侧平台的(8.3±1.6)分(t=12.173,P=0.000)。根据Mankin评分结果在60个标本中,14个为OA早期,可见软骨浅表层裂隙、潮线复制和软骨下骨增厚;19个为OA中期,可见软骨深层裂隙、多发软骨下骨吸收陷窝和明显增厚的软骨下骨;27个为OA晚期,可见软骨全层缺失、软骨内化骨和"象牙化"软骨下骨。软骨和软骨下骨结构参数测定示:内侧平台TAC厚度显著低于外侧平台,ACC/TAC比值、BV/TV及SCP厚度显著高于外侧平台,差异均有统计学意义(P<0.05)。内、外侧平台ACC厚度比较,差异无统计学意义(P>0.05)。结论钙化层和软骨下骨可能在OA发生与进展中发挥了重要作用。     

Purified staphylococcal culture medium stimulates neutral metalloprotease secretion from human articular cartilage.

Human articular cartilage released significantly increased levels of metal-dependent enzymes capable of degrading collagen, casein, and gelatin at a neutral pH following exposure to a sterile, purified fraction of Staphylococcus aureus culture medium. Neutral metalloprotease activity was determined by radiolabeled substrate assays and substrate gel analysis. The enzymes were activated with 4-aminophenylmercuric acetate and were inhibited by 1,10-phenanthroline and ethylenediamine tetraacetic acid. Protein immunoblots demonstrated that type I collagenase and stromelysin (matrix metalloproteinase III) secretion was increased following staphylococcal medium challenge. The profile of enzymatic activity induced by staphylococcal medium was directly comparable to that observed with interleukin-1, which was used as a positive control. The staphylococcal medium had no inherent proteolytic activity. Increased production of the neutral metalloproteases collagenase and stromelysin may significantly contribute to the extensive cartilage destruction noted in staphylococcal septic arthritis.     

Alterations in endogenous osteogenic protein-1 with degeneration of human articular cartilage.

A synchronized balance between synthesis and breakdown of extracellular matrix (ECM) molecules in normal articular cartilage is disturbed in osteoarthritis (OA). The focus of our study is the anabolic factor, osteogenic protein-1 (OP-1) that is expressed in articular cartilage and is able to induce the synthesis of ECM components. The major aim was to investigate both qualitatively and quantitatively endogenous OP-1 in normal, degenerative, and OA cartilage. Normal and degenerative cartilage was obtained at autopsies from femoral condyles of human organ donors with no documented history of joint disease; OA cartilage was obtained from patients undergoing joint arthroplasty. Appearance of donor cartilage was evaluated by Collins scale, where normal cartilage is assigned grades 0-1, and degenerated cartilage is assigned grades 2-4. OP-1 mRNA expression was assessed by RT-PCR; OP-1 protein (pro- and active forms) was qualitatively analyzed by Western blotting and quantified by OP-1 ELISA. The highest levels of OP-1 expression (mRNA and protein) were detected in normal cartilage of grade 0. The concentration of OP-1 protein was about 50 ng per gram cartilage dry weight. With the progression of cartilage degeneration (increased Collins grades and OA) OP-1 protein was down-regulated up to 9-fold. These changes affected primarily the active form of OP-1. OP-1 message also declined in cartilages with the increase of degenerative changes. In conclusion, an overall decrease in endogenous OP-1 in degenerated and OA tissue suggests that OP-1 could be one of the factors responsible for normal homeostasis and matrix integrity in cartilage.     

Injury and repair of articular cartilage: Related scientific issues

Articular cartilage (AC) is the soft tissue lining the ends of bones in diarthrodial joints. It is responsible for providinglubrication and compressive stiffness to the joint during articulation while responding viscoelastically to mechanical loading. Injury of the tissue caused by trauma or disease can be devastating to joint function as these mechanisms fail. Because of this, it is essential to review the basic science underlying the mechanical roles AC plays while healthy, the biomechanical and biological perspectives of the injury and repair processes, and the current repair techniques available for injured AC. This is done in an effort to further our understanding of the healing capacity of AC and facilitate new efforts into AC repair.     

Prevalence of articular cartilage degeneration in the ankle and knee joints of human organ donors

The prevalence of osteoarthritis (OA) is higher in some joints than in others. Fibrillation and full-thickness cartilage defects in the knee have been considered to be evidence of developing OA (pre-OA). While similar changes have been reported in the ankle (talocrural joint), the frequency of these changes is much higher than expected if the degeneration represents pre-OA. These observations suggest that in the ankle degenerative changes do not proceed to OA. The current study was to determine the prevalence of articular cartilage degeneration in ankles in a population of 470 bone donors with no history of joint disease. Knees from 50 donors were also available. Our data suggest that degeneration in the ankle cartilage does not appear to be a normal part of aging, was more frequent in men than women, increased with age, and occurred most often in both limbs with the same severity. In those donors with degeneration in the ankle, the knee also showed degenerative changes with an equal or higher grade. These data suggest that factors (such as altered mechanics) responsible for degeneration in one limb also cause changes in the contralateral limb and that factors affecting the ankle joints also appear to influence the knee joints. Received for publication on Dec. 2, 1998; accepted on April 22, 1999     

Comparison of gene expression patterns in articular cartilage and dedifferentiated articular chondrocytes

During monolayer culture, articular chondrocytes dedifferentiate into fibroblast‐like cells. The mechanisms underlying this process are poorly understood. We sought to further characterize dedifferentiation by identifying an extended panel of genes that distinguish articular cartilage from dedifferentiated chondrocytes. Thirty‐nine candidate marker‐genes were identified from previous studies on articular‐cartilage gene‐expression. Real‐time PCR was used to evaluate the mRNA levels for these candidates in calf articular cartilage and dedifferentiated articular chondrocytes. Twenty‐two of the candidate marker genes exhibited at least a two‐fold difference in gene expression in the two cell types. Twelve of these genes had at least a ten‐fold difference in gene expression. Tenascin C (TNC), type I collagen (COL1A1), and hypoxia‐inducible factor 1 alpha (HIF1α) showed the highest relative expression levels in dedifferentiated chonodrocytes. Type II collagen (COL2A1), type XI collagen (COL11A2), and superficial zone protein (SZP) showed the highest relative expression levels in articular cartilage. In contrast to previous findings, fibromodulin mRNA, and protein levels were higher in dedifferentiated chondrocytes. Compared to smaller subsets of markers, this panel of 12 highly differentially expressed genes may more precisely distinguish articular cartilage from dedifferentiated chondrocytes. Since many of the genes up‐regulated in dedifferentiated chondrocytes are also expressed during cartilage development, dedifferentiated chondrocytes may possess features of cartilage precursor cells. © 2011 Orthopaedic Research Society Published by Wiley Periodicals, Inc. J Orthop Res 30:234–245, 2012     

Determination of characteristics of degenerative joint disease using optical coherence tomography and polarization sensitive optical coherence tomography

BACKGROUND AND OBJECTIVES: Previous studies have demonstrated that optical coherence tomography (OCT) could be used to delineate alterations in the microstructure of cartilage, and have suggested that changes in the polarization state of light as detected by OCT could provide information on the birefringence properties of articular cartilage as influenced by disease. In this study we have used both OCT and polarization sensitive optical coherence tomography (PS-OCT) technologies to evaluate normal and abnormal bovine articular cartilage according to established structural, organizational, and birefringent characteristics of degenerative joint disease (DJD) in order to determine if this technology can be used to differentiate various stages of DJD as a minimally invasive imaging tool. MATERIALS AND METHODS: Fresh bovine femoral-tibial joints were obtained from an abattoir, and 45 cartilage specimens were harvested from 8 tibial plateaus. Whole ex vivo specimens of normal and degenerative articular cartilage were imaged by both OCT and PS-OCT, then fixed and processed for histological evaluation. OCT/PS-OCT images and corresponding histology sections of each specimen were scored according to a modified Mankin structural grading scale and compared. RESULTS: OCT and PS-OCT imaging allowed structural evaluation of intact articular cartilage along a 6 mm surface length to a depth of 2 mm with a transverse resolution of 12 microm and an axial resolution of 10 microm. The OCT and PS-OCT images demonstrated characteristic alterations in the structure of articular cartilage with a high correlation to histological evaluation (kappa = 0.776). The OCT images were able to demonstrate early to advanced structural changes of articular cartilage while the optical phase retardation images obtained by PS-OCT imaging were able to discriminate areas where disorganization of the cartilage matrix was present, however, these characteristics are much different than those reported where OCT images alone were used to characterize tissue birefringence. No evidence of differences in OCT or PS-OCT images were detected between specimens of similar structural characteristics where proteoglycan was judged present or absent by safranin-O Fast Green staining. CONCLUSIONS: The combined use of OCT and PS-OCT technologies to obtain images from a single system is able to demonstrate and discriminate between characteristics of very early stages of surface irregularities not previously reported for OCT imaging, to deep clefts and collagen matrix disorganization for tissue at depths of up to 2 mm with good correlation to histology. PS-OCT and accumulated optical phase retardation images of articular cartilage as constructed from alterations in Stokes vector parameters appear to give a valuable but different assessment of alterations in tissue birefringence and organization than have been reported for OCT images obtained with the use of polarized or non-polarized light sources. This is the first time that alterations in the polarization state of light reflected from within the tissue have been demonstrated to be consistent with changes observed in the orientation and organization of the collagen matrix in advanced stages of DJD. The degree of phase transformation of light reflected from within the tissue as determined by PS-OCT imaging does not appear to be altered by the presence or absence of proteoglycan.     

Imaging of Articular Cartilage

Since the advent of arthroscopy and MRI, clinicians have been able to directly image articular cartilage. Significant strides have been made to improve MRI technology to permit nondestructive imaging and assessment of articular cartilage. Development of new cartilage-specific MRI sequences and MRI techniques to evaluate cartilage matrix composition permit earlier diagnosis of cartilage injury and degeneration. Although the current standard for articular cartilage assessment continues to be visual assessment through arthroscopic surface imaging and probing, introduction of novel cross-sectional imaging technologies such as OCT will similarly augment the diagnostic capacity of arthroscopic assessment of articular cartilage. Continued development of new methods to image articular cartilage will enhance the ability of clinicians in identifying potentially treatable areas of early cartilage damage. Improved early diagnosis and treatment may lead to methods to prevent or delay the onset of disabling osteoarthritis.     

同种异体软骨移植修复关节软骨缺损实验研究

目的 采用兔膝关节软骨标本经打孔梯度降温冻存后行同种异体移植,研究打孔梯度降温冻存对兔关节软骨的影响及其修复关节软骨缺损的效果.方法 自16只2月龄新西兰白兔膝关节股骨髌面取分别取3块骨软骨移植物,随机分为3组.Ⅰ组为实验组,在软骨上以3 mm×3 mm矩阵打孔,Ⅱ、Ⅲ组为对照组,不打孔.分别将软骨标本置于二甲基亚砜冷冻保护溶液中,并经梯度降温至-80℃(Ⅰ、Ⅱ组)或直接置于-80℃(Ⅲ组)保存1周,复温后移植到成年兔相应膝关节部位.术后分批处死动物,通过对移植物的大体形态学、组织学、免疫组化染色光镜观察,研究各组移植物保存效果的差异.结果 Ⅰ、Ⅱ组光镜观察结果明显优于Ⅲ组;Ⅰ组与Ⅱ组结果差异不明显,但Ⅰ组对中间层软骨组织的保护明显加强.结论 关节软骨的梯度降温冷冻保存效果明显优于快速降温冷冻保存,且关节软骨打孔冷冻保存对深层软骨细胞有一定的保护作用,可提高软骨细胞存活率,延缓移植软骨组织的退变过程.     

壳聚糖在关节软骨组织工程中应用的研究进展

关节软骨一旦被损伤，因其缺乏自身血液循环系统，仅靠关节滑液提供大部分营养。随着年龄的增长，软骨细胞的合成能力下降，故关节软骨损伤后很难修复。虽然40多年来许多修复技术被广泛应用，但是至今还没有一种方法可以让受损软骨持续再生，从而达到完全修复的目的。组织工程的兴起在软骨的再生以及受损软骨的治疗方面显示出巨大的潜力。支架材料作为人工细胞外基质承载种子细胞是组织工程研究的重要内容之一。近年来，以壳聚糖为支架的材料及其在矫形组织工程中的应用正受到越来越多的关注。壳聚糖是一种理想的高分子生物材料，它具有机体反应小、天然抗菌性以及具有可任意塑性如多孔结构的特点，使其能够适合细胞的内在生长以及骨的传导，在组织工程中显示出巨大的应用价值。     

Changes in chondrocyte gene expression following in vitro impaction of porcine articular cartilage in an impact injury model

Our objective was to monitor chondrocyte gene expression at 0, 3, 7, and 14 days following in vitro impaction to the articular surface of porcine patellae. Patellar facets were either axially impacted with a cylindrical impactor (25 mm/s loading rate) to a load level of 2,000 N or not impacted to serve as controls. After being placed in organ culture for 0, 3, 7, or 14 days, total RNA was isolated from full thickness cartilage slices and gene expression measured for 17 genes by quantitative real‐time RT‐PCR. Targeted genes included those encoding proteins involved with biological stress, inflammation, or anabolism and catabolism of cartilage extracellular matrix. Some gene expression changes were detected on the day of impaction, but most significant changes occurred at 14 days in culture. At 14 days in culture, 10 of the 17 genes were differentially expressed with col1a1 most significantly up‐regulated in the impacted samples, suggesting impacted chondrocytes may have reverted to a fibroblast‐like phenotype. © 2012 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 31: 385–391, 2013