López-Torres Irene Isabel, Sanz-Ruíz Pablo, Navarro-García Federico, León-Román Victor Estuardo, Vaquero-Martín Javier
Hospital General Universitario Gregorio Marañón, Madrid, Spain.
Hospital General Universitario Gregorio Marañón, Madrid, Spain; Surgery Department, Faculty of Medicine, Universidad Complutense, Madrid, Spain.
Knee. 2020 Jun;27(3):1106-1112. doi: 10.1016/j.knee.2019.12.012. Epub 2020 Jan 22.
Infection after arthroplasty (prosthetic joint infection; PJI) is a devastating complication that can lead to functional loss of the affected limb. The purpose of the present study is to develop an animal model of PJI using a three-dimensional printed species-specific implant, which is a step forward for future research to develop new therapeutic strategies.
Fifteen New Zealand White rabbits were employed to reproduce PJI by intra-articular inoculation of 10 cfu/ml of Staphylococcus aureus ATCC® 29213. Three-dimensional printing technology was used to design a species-specific four-millimeter-thick implant maintaining the anatomical irregularities of the tibial-articular surface. Response to bacterial inoculation was monitored by clinical (weight and temperature), hematological (leukocyte, lymphocyte and platelet counts) and biochemical (erythrocyte sedimentation rate) analyses at the time of inoculation and seven days thereafter, when microbiological samples for culture were also taken.
All animals recovered from surgery and all displayed full weight-bearing four days postoperatively. Fourteen of the 15 tested animals (93.3%) presented positive microbiological cultures. A statistically significant increase was found in the number of platelets and leukocytes, as well as a significant decrease in the percentage of lymphocytes, with P = 0.0001 in all cases.
An experimental model faithfully reproducing the periprosthetic infection environment and achieving a high rate of infection has been designed. The use of three-dimensional printed species-specific implants allows rapid postoperative recovery of animals and the development of a stable biofilm. These characteristics make it an interesting model to study its pathogenesis and possible therapeutic strategies.
关节置换术后感染(人工关节感染;PJI)是一种严重的并发症,可导致患肢功能丧失。本研究的目的是使用三维打印的物种特异性植入物建立PJI动物模型,这是未来开发新治疗策略研究的一个进步。
采用15只新西兰白兔,通过关节内接种10 cfu/ml的金黄色葡萄球菌ATCC® 29213来复制PJI。利用三维打印技术设计一种物种特异性的4毫米厚植入物,保留胫骨关节表面的解剖不规则性。在接种时及接种后7天,通过临床(体重和体温)、血液学(白细胞、淋巴细胞和血小板计数)和生化(红细胞沉降率)分析监测对细菌接种的反应,此时也采集用于培养的微生物样本。
所有动物术后均恢复,术后4天均能完全负重。15只受试动物中有14只(93.3%)微生物培养呈阳性。血小板和白细胞数量有统计学意义的增加,淋巴细胞百分比有显著下降,所有情况P = 0.0001。
已设计出一种能如实再现假体周围感染环境并实现高感染率的实验模型。使用三维打印的物种特异性植入物可使动物术后快速恢复并形成稳定的生物膜。这些特性使其成为研究其发病机制和可能治疗策略的一个有趣模型。
