Dog sniffing biomechanic responses in an odor detection test of odorants with differing physical properties

IF 2.7 2区 农林科学 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE
Lydia R Burnett, Nick R Hebdon, Pete A Stevens, Monica D Moljo, Lindsay D Waldrop, Lauryn E DeGreeff
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Abstract

Dogs are utilized in forensic science for their extensive scent detection capabilities. They are often considered the “gold standard” in field detection for targets such as illicit drugs and explosives. Despite their prevalence in the field, relatively little is known about how dogs interact with and transport volatile organic compounds through their olfactory system. In this study, two groups of dogs were utilized – Sport detection dogs (n=19) that participate in the National Association of Canine Scent Work and have achieved advanced standing through training and successful search competitions and law enforcement explosive detection dogs (n=8) which were included for comparison. Both groups were presented with two target odorants having differing molecular properties, 2-ethyl-1-hexanol and ammonia, two non-target odorants, 1-bromooctane and methyl benzoate, and a negative control. Canines were tested prior to experience with the target odorants, when all odorants were novel, after some brief training with the target odorants, and after longer training time with the target odorants. The non-target odorants were never used in training. Sniffing was measured using flow sensors embedded in a wall immediately in front of the odorants held in a closed cylinder. Sensor data was used to calculate sniff flow rate, frequency (sniffs per seconds) and volume. Results indicated no difference in sniffing dynamics between target odorants; however, sniffing frequency increased significantly with increased experience with the target odorants (Wilcoxon rank sum exact test, W= 148, p=6×10-5). Sniff volume and flow rate showed a positive correlation to body mass for all sport detection dogs (slope = 2.71, F(1,17)= 9.48, p= 0.007, R2= 0.32), though the R2 was low, indicating other factors at play. Law enforcement detection dogs were shown to take in significantly higher mean total sniff volumes (Wilcoxon rank sum exact test: W= 7, p=10-4) and volume flow rates (Wilcoxon rank sum exact test: W= 5, p=6×10-5) compared to the sport detection dogs, but the sniff frequency remained similar for both groups.
不同物理性质气味检测试验中狗嗅闻的生物力学反应
法医学中使用警犬是因为它们具有广泛的气味探测能力。它们通常被认为是现场检测非法药物和爆炸物等目标的 "黄金标准"。尽管嗅探犬在野外工作中非常普遍,但人们对嗅探犬如何通过嗅觉系统与挥发性有机化合物相互作用并将其转移的了解却相对较少。在这项研究中,使用了两组狗--参加全国犬类嗅觉工作协会并通过训练和成功的搜索比赛获得高级资格的运动侦查犬(数量为 19 只)和执法爆炸物侦查犬(数量为 8 只)作为对比。两组犬都接受了分子性质不同的两种目标气味(2-乙基-1-己醇和氨)、两种非目标气味(1-溴辛烷和苯甲酸甲酯)和一种阴性对照。犬类在接触目标气味之前、所有气味都是新的时候、经过目标气味的短暂训练之后以及经过目标气味的较长时间训练之后接受测试。训练中从未使用过非目标气味。测量嗅觉的方法是使用嵌在紧靠封闭圆筒内气味剂前方墙壁上的流量传感器。传感器数据用于计算嗅闻流速、频率(每秒嗅闻次数)和嗅闻量。结果表明,不同目标气味剂之间的嗅闻动态没有差异;但是,嗅闻频率会随着目标气味剂使用经验的增加而显著增加(Wilcoxon 秩和精确检验,W= 148,p=6×10-5)。所有运动型侦查犬的嗅闻量和流速与体重呈正相关(斜率 = 2.71,F(1,17)= 9.48,p= 0.007,R2= 0.32),但 R2 较低,表明还有其他因素在起作用。与运动侦查犬相比,执法侦查犬吸入的平均总嗅探量(Wilcoxon 秩和精确检验:W= 7,p=10-4)和嗅探流量(Wilcoxon 秩和精确检验:W= 5,p=6×10-5)明显更高,但两组的嗅探频率仍然相似。
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来源期刊
Journal of animal science
Journal of animal science 农林科学-奶制品与动物科学
CiteScore
4.80
自引率
12.10%
发文量
1589
审稿时长
3 months
期刊介绍: The Journal of Animal Science (JAS) is the premier journal for animal science and serves as the leading source of new knowledge and perspective in this area. JAS publishes more than 500 fully reviewed research articles, invited reviews, technical notes, and letters to the editor each year. Articles published in JAS encompass a broad range of research topics in animal production and fundamental aspects of genetics, nutrition, physiology, and preparation and utilization of animal products. Articles typically report research with beef cattle, companion animals, goats, horses, pigs, and sheep; however, studies involving other farm animals, aquatic and wildlife species, and laboratory animal species that address fundamental questions related to livestock and companion animal biology will be considered for publication.
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