Leung Alina A, Lou Jerry J, Mareninov Sergey, Silver Steven S, Routbort Mark J, Riben Michael, Andrechak Gary, Yong William H
Department of Pathology and Laboratory Medicine (Neuropathology), David Geffen School of Medicine at UCLA, Los Angeles, CA.
J Pathol Inform. 2010 Oct 1;1:21. doi: 10.4103/2153-3539.70710.
Radio frequency identification (RFID) tags have potential for use in identifying and tracking biospecimens in anatomic pathology and biorepository laboratories. However, there is little to no data on the tolerance of tags to solutions, solvents, temperatures, and pressures likely to be encountered in the laboratory. The functioning of the Hitachi Mu-chip RFID tag, a candidate for pathology use, was evaluated under such conditions.
The RFID tags were affixed to cryovials containing tissue or media, glass slides, and tissue cassettes. The tags were interrogated for readability before and after each testing condition or cycle. Individual tags were subjected to only one testing condition but for multiple cycles. Testing conditions were: 1) Ten wet autoclave cycles (121°C, 15 psi); 2) Ten dry autoclave cycles (121°C, 26 psi); 3) Ten tissue processor cycles; 4) Ten hematoxylin and eosin (H&E) staining cycles; 5) Ten antigen retrieval pressure cooker cycles (125°C, 15 psi); 6) 75°C for seven days; 7) 75-59 °C day/night cycles for 7 days; 8) -80°C, -150°C, or -196°C for 12 months; 9) Fifty freeze-thaw cycles (-196°C to 22°C).
One hundred percent of tags exposed to cold temperatures from -80 to -196 °C (80 tags, 1120 successful reads), high temperatures from 52 to 75°C (40 tags, 420 reads), H & E staining (20 tags, 200 reads), pressure cooker antigen retrieval (20 tags, 200 reads), and wet autoclaving (20 tags, 200 reads) functioned well throughout and after testing. Of note, all 20 tested tags tolerated 50 freeze-thaw cycles and all 60 tags subjected to sustained freezing temperatures were readable after 1 year. One dry autoclaved tag survived nine cycles but failed after the tenth. The remaining 19 tags were readable after all 10 dry autoclave cycles. One tag failed after the first tissue processing cycle while the remaining 19 tags survived all 10 tissue processing cycles.
In this preliminary study, these RFID tags show a high-degree of tolerance to tested solutions, solvents, temperature, and pressure conditions. However, a measurable failure rate is detectable under some circumstances and redundant identification systems such as barcodes may be required with the deployment of RFID systems. We have delineated testing protocols that may be used as a framework for preliminary assessments of candidate RFID tag tolerance to laboratory conditions.
射频识别(RFID)标签有潜力用于解剖病理学和生物样本库实验室中生物样本的识别和追踪。然而,关于标签在实验室可能遇到的溶液、溶剂、温度和压力下的耐受性数据很少甚至没有。在这样的条件下评估了日立μ芯片RFID标签(一种有望用于病理学的标签)的功能。
将RFID标签粘贴到装有组织或培养基的冻存管、载玻片和组织盒上。在每个测试条件或循环前后对标签进行可读性检测。单个标签仅接受一种测试条件,但进行多个循环。测试条件如下:1)十次湿热灭菌循环(121°C,15磅力/平方英寸);2)十次干热灭菌循环(121°C,26磅力/平方英寸);3)十次组织处理循环;4)十次苏木精和伊红(H&E)染色循环;5)十次抗原修复高压锅循环(125°C,15磅力/平方英寸);6)75°C下放置七天; 7)75 - 59°C昼夜循环七天;8)-80°C、-150°C或-196°C下放置12个月;9)五十次冻融循环(-196°C至22°C)。
暴露于-80至-196°C低温(80个标签,1120次成功读取)、52至75°C高温(40个标签,420次读取)、H&E染色(20个标签,200次读取)、高压锅抗原修复(20个标签,200次读取)和湿热灭菌(20个标签,200次读取)的标签在测试期间及之后均运行良好。值得注意的是,所有20个测试标签耐受了五十次冻融循环,所有60个经历持续冷冻温度的标签在1年后仍可读取。一个干热灭菌的标签在九次循环后存活,但在第十次失败。其余19个标签在所有10次干热灭菌循环后仍可读取。一个标签在第一次组织处理循环后失败,而其余19个标签在所有10次组织处理循环后存活。
在这项初步研究中,这些RFID标签对测试的溶液、溶剂、温度和压力条件表现出高度耐受性。然而,在某些情况下可检测到可测量的故障率,并且在部署RFID系统时可能需要诸如条形码之类的冗余识别系统。我们已经制定了测试方案,可作为初步评估候选RFID标签对实验室条件耐受性的框架。
