The Walter and Eliza Hall Institute of Medical Research, Melbourne, Victoria, Australia; Department of Medical Biology, The Faculty of Medicine, Dentistry and Health Sciences, The University of Melbourne, Melbourne, Victoria, Australia.
Department of Helminthology, Faculty for Tropical Medicine, Mahidol University, Bangkok, Thailand.
Int J Parasitol. 2021 Aug;51(9):741-748. doi: 10.1016/j.ijpara.2021.01.002. Epub 2021 Mar 26.
Molecular studies of gastrointestinal infections or microbiotas require either rapid sample processing or effective interim preservation. This is difficult in remote settings in low-income countries, where the majority of the global infectious disease burden exists. Processing or freezing of samples immediately upon collection is often not feasible and the cost of commercial preservatives is prohibitive. We compared fresh freezing (the 'gold standard' method), with low-cost chemical preservation in (i) a salt-based buffer consisting of DMSO, EDTA and NaCl (DESS) or (ii) 2.5% potassium dichromate (PD), for soil-transmitted helminth detection and microbiota characterisation in pre-school and school-aged children from north-western Thailand. Fresh frozen samples were frozen at -20°C on collection and maintained at -80°C within ~3 days of collection until molecular analysis, with international shipping on dry ice. In contrast, chemically preserved samples were collected and stored at ~4°C, transported on wet ice and only stored at -20°C on arrival in Australia ~8 weeks after collection, with international shipping on wet ice. DESS and PD provided better sensitivity for STH diagnosis, estimating higher infection rates (>80% for Ascaris lumbricoides and >60% for Trichuris trichiura; versus 56% and 15% for these parasites in fresh frozen samples) and egg abundance (inferred as gene copy number estimates). All methods performed similarly for microbiota preservation, showing no significant differences in alpha-diversity based on overall richness or inverted Simpson's Index. All three methods performed similarly for RNA and protein preservation in a small subset of samples. Overall, DESS provided the best performance, with the added benefit of being non-toxic, compared with PD, hence making it particularly applicable for studies in remote and resource-poor settings.
胃肠道感染或微生物组的分子研究需要快速的样本处理或有效的临时保存。在低收入国家的偏远地区,这是困难的,因为那里存在着全球大部分传染病负担。在采集后立即处理或冷冻样本通常是不可行的,而且商业防腐剂的成本是令人望而却步的。我们比较了新鲜冷冻(“黄金标准”方法)与低成本化学保存方法,即在(i)含有 DMSO、EDTA 和 NaCl 的盐基缓冲液(DESS)或(ii)2.5%重铬酸钾(PD)中,用于检测土壤传播性蠕虫和泰国西北部学龄前和学龄儿童的微生物组特征。新鲜冷冻样本在采集时在-20°C 下冷冻,并在采集后约 3 天内保持在-80°C,直到进行分子分析,使用干冰进行国际运输。相比之下,化学保存的样本在采集后在~4°C 下收集和储存,在湿冰上运输,并在抵达澳大利亚后仅在-20°C 下储存约 8 周,使用湿冰进行国际运输。DESS 和 PD 提供了更好的 STH 诊断灵敏度,估计更高的感染率(对于蛔虫为>80%,对于鞭虫为>60%;而新鲜冷冻样本中这些寄生虫的感染率分别为 56%和 15%)和卵丰度(推断为基因拷贝数估计)。所有方法在微生物组保存方面的表现相似,基于总体丰富度或倒置 Simpson 指数,没有显著差异。所有三种方法在一小部分样本的 RNA 和蛋白质保存方面的表现相似。总的来说,DESS 表现最好,与 PD 相比,毒性较小,因此特别适用于偏远和资源匮乏地区的研究。
