Myler Heather A, McVay Sami, Kratzsch Juergen
Ambrx, Inc., 10975 North Torrey Pines Road, La Jolla, California 92037, USA.
J Pharmacol Toxicol Methods. 2010 Mar-Apr;61(2):92-7. doi: 10.1016/j.vascn.2009.12.004. Epub 2010 Jan 4.
The ability to quantify systemic concentrations of protein therapeutics is complicated by the presence of endogenous analyte, specific binding proteins, and nonspecific matrix components in biological matrices (Lee & Ma, 2007). Further complications can be introduced following pegylation whereby polyethylene glycol (PEG) impedes epitope recognition. Due to substantial interference from high affinity binding proteins and the inability to measure systemic drug concentrations under normal conditions, acid dissociation was implemented to facilitate the pharmacokinetic evaluation of clinical samples containing pegylated human growth hormone (PEG-hGH).
A sandwich electrochemiluminescent immunosorbent assay (ECLA) was employed using an anti-PEG capture, anti-hGH detection format, thereby eliminating cross-reactivity with endogenous compound. Samples were acid treated with glycine buffered hydrochloric acid (approximately pH 2.0) to dissociate PEG-hGH from serum resident growth hormone binding protein (GHBP; 3). After neutralization with a HEPES-based neutralizing buffer, samples were diluted in a casein-based assay buffer containing 0.2% I-block, 0.1% Tween-20, 2M NaCl, and 10% normal mouse serum to eliminate nonspecific matrix effects. Meso Scale Discovery (MSD) technology was employed to achieve sensitivity requirements.
The drug detection assay was validated in the presence and absence of acid dissociation. Validation parameters included: intra- and inter-assay accuracy and precision, selectivity (>60 lots of normal and growth hormone deficient human serum), cross-reactivity/specificity (Genotropin, hemoglobin, lipid, and bilirubin), dilutional linearity and stability (DeSilva et al., 2003; Shah et al., 1992; Smolec et al., 2005 Viswanathan et al., 2007; Food and Drug Administration, 2001). A 10-fold molar excess of GHBP was found to decrease PEG-hGH detection by >90% while acid dissociation was shown to recover >80% of the analyte. PEG-hGH clinical pharmacokinetic samples were analyzed with and without acid treatment. Only 38% of the mid-dose samples were quantifiable without acid treatment while 92% were quantifiable after acid dissociation.
The implementation of acid dissociation was found to substantially increase the number of quantifiable pharmacokinetic samples over the drug exposure time course and contributed significantly to the robustness of pharmacokinetic evaluation.
蛋白质治疗药物全身浓度的量化能力因生物基质中存在内源性分析物、特异性结合蛋白和非特异性基质成分而变得复杂(Lee和Ma,2007年)。聚乙二醇化后会引发更多复杂情况,即聚乙二醇(PEG)会阻碍表位识别。由于高亲和力结合蛋白的大量干扰以及无法在正常条件下测量全身药物浓度,因此采用酸解离来促进对含聚乙二醇化人生长激素(PEG-hGH)临床样品的药代动力学评估。
采用夹心电化学发光免疫吸附测定法(ECLA),使用抗PEG捕获、抗hGH检测形式,从而消除与内源性化合物的交叉反应性。样品用甘氨酸缓冲盐酸(约pH 2.0)进行酸处理,以使PEG-hGH与血清中存在的生长激素结合蛋白(GHBP;3)解离。用基于HEPES的中和缓冲液中和后,将样品在含有0.2% I-block、0.1%吐温-20、2M NaCl和10%正常小鼠血清的酪蛋白基测定缓冲液中稀释,以消除非特异性基质效应。采用Meso Scale Discovery(MSD)技术来满足灵敏度要求。
在有和没有酸解离的情况下对药物检测测定法进行了验证。验证参数包括:批内和批间准确性和精密度、选择性(超过60批正常和生长激素缺乏的人血清)、交叉反应性/特异性(基因重组人生长激素、血红蛋白、脂质和胆红素)、稀释线性和稳定性(DeSilva等人,2003年;Shah等人,1992年;Smolec等人,2005年;Viswanathan等人,2007年;美国食品药品监督管理局,2001年)。发现10倍摩尔过量的GHBP会使PEG-hGH检测降低>90%,而酸解离显示可回收>80%的分析物。对PEG-hGH临床药代动力学样品进行了酸处理和未酸处理的分析。未进行酸处理时,只有38%的中剂量样品可定量,而酸解离后92%的样品可定量。
发现酸解离的实施在药物暴露时间过程中大幅增加了可定量药代动力学样品的数量,并对药代动力学评估的稳健性做出了重大贡献。
