Particles in protein therapeutics, composed of aggregated protein monomers, may cause an immunogenic response in patients. Consequently, industry and the FDA desire more accurate methods for counting and characterizing particles. Unlike many manufacturing impurities, protein particles have a refractive index very close to that of the matrix solution. In this paper, we describe some of the measurement challenges for the common optical methods of brightrfield microscopy and light obscuration. The paniculate refractive index is a key unknown parameter in the effort to standardize counting of protein particles. At NIST, we are developing two types of reference materials that mimic the properties of protein particles to support the validation of these two optical methods. We have developed a polymer-based protein surrogate based on the partially fluorinated polymer ethylene tetrafluoroethylene (ETFE). Mechanical abrasion of the ETFE followed by size filtration produces a polydisperse suspension of very rugged particles with a morphology quite similar to protein particles. In another approach, we have created artificial polymer particles as small as 3 p x 4 um x 40 um in large quantities using photolithographic methods developed for the semiconductor industry. Future work will focus on reducing the optical contrast of these particles in order to better mimic typical protein particles. These reference materials will provide a stringent test of the sensitivity and morphological measurements of optical particle-counting and particle-characterization instruments.
展开▼
机译:蛋白质治疗剂中的颗粒由聚集的蛋白质单体组成,可能导致患者产生免疫原性应答。因此,工业界和FDA需要更精确的方法来计数和表征颗粒。与许多制造杂质不同,蛋白质颗粒的折射率非常接近基质溶液的折射率。在本文中,我们描述了明场显微镜和光遮蔽的常见光学方法的一些测量挑战。在标准化蛋白质颗粒计数的过程中,圆锥形折射率是关键的未知参数。在NIST,我们正在开发两种参考材料,它们可以模拟蛋白质颗粒的特性,以支持这两种光学方法的验证。我们已经基于部分氟化的聚合物乙烯四氟乙烯(ETFE)开发了基于聚合物的蛋白质替代品。对ETFE进行机械磨损,然后进行尺寸过滤,会形成非常坚固的颗粒的多分散悬浮液,其形态与蛋白质颗粒非常相似。在另一种方法中,我们使用为半导体工业开发的光刻方法,大量制造了3p x 4 um x 40 um的人造聚合物颗粒。未来的工作将集中在降低这些颗粒的光学对比度上,以便更好地模仿典型的蛋白质颗粒。这些参考材料将对光学粒子计数和粒子表征仪器的灵敏度和形态学测量提供严格的测试。
展开▼
