Sandrine Trudeau, Clara Bourel-Conroy, Pauline Hérambert, Raphaël Guatteo, Sébastien Buczinski
{"title":"用ATP光度法监测初乳收获和分配设备的清洁度,建议改善法国奶牛场的卫生习惯。","authors":"Sandrine Trudeau, Clara Bourel-Conroy, Pauline Hérambert, Raphaël Guatteo, Sébastien Buczinski","doi":"10.3168/jds.2025-26832","DOIUrl":null,"url":null,"abstract":"<p><p>This observational study evaluated the effects of practical hygiene recommendations on cleanliness and bacterial contamination of equipment used to harvest and feed colostrum on 8 French dairy farms. The study was conducted in 2 phases: before (phase 1) and after (phase 2) the implementation of farm-specific recommendations. During each phase, equipment cleanliness (e.g., robot-compatible buckets, milking buckets, transfer buckets, bottles, nipples, nipple buckets, drenchers, and esophageal tube feeders [ET]) was assessed using ATP luminometry (through direct surface [ATP-S] and rinsing liquid [ATP-L] swabbing, expressed in relative light units [RLU]), visual scoring, and culture-based bacteriological analysis. Fresh colostrum samples were also collected and analyzed during each phase. A self-reported questionnaire administered during phase 1 identified critical control points for colostrum contamination, which informed the formulation of practical hygiene recommendations. Contamination thresholds were defined as ≥100,000 cfu/mL for total bacterial count (TBC) and ≥10,000 cfu/mL for total coliform count (TCC). Hygiene practices related to the operator, cow teats, and equipment varied considerably among farms, as did adherence to the recommended practices. Overall, lower RLU values were recorded on equipment surfaces during phase 2 compared with phase 1 (ATP-L: -1.51 log [±0.24], P < 0.001; ATP-S: -1.15 log [±0.24], P < 0.001). These reductions were associated with good operator hygiene practices and the use of brand-new equipment. Lower levels of contamination of colostrum samples were found in phase 2 (TBC: -0.92 log [±0.19], P < 0.001; TCC: -1.14 log [±0.30], P < 0.001), associated with good operator hygiene practices. Significant correlations (Spearman's rho, r<sub>s</sub>) were observed between visual cleanliness scores and RLU values from both swabbing techniques, as well as between ATP-L RLU values and bacterial counts (TBC: r<sub>s</sub> = 0.744, 95% CI: 0.556-0.859, P < 0.0001; TCC: r<sub>s</sub> = 0.475, 95% CI: 0.183-0.690, P < 0.002). Based on ATP-L swab results, optimal luminometry cutpoints maximizing (sensitivity + specificity) were identified at ≥6,950 RLU (sensitivity: 79.17%; specificity: 100%) for TBC, and ≥11,912 RLU (sensitivity: 88.89%; specificity: 70.97%) for TCC. This study demonstrates that targeted hygiene improvements can significantly reduce both equipment surface and colostrum bacterial contamination and support the use of ATP luminometry as a practical tool for hygiene monitoring on dairy farms.</p>","PeriodicalId":354,"journal":{"name":"Journal of Dairy Science","volume":" ","pages":""},"PeriodicalIF":4.4000,"publicationDate":"2025-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Monitoring colostrum harvesting and distribution equipment cleanliness with ATP luminometry before and after recommendations to improve hygiene practices in French dairy farms.\",\"authors\":\"Sandrine Trudeau, Clara Bourel-Conroy, Pauline Hérambert, Raphaël Guatteo, Sébastien Buczinski\",\"doi\":\"10.3168/jds.2025-26832\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>This observational study evaluated the effects of practical hygiene recommendations on cleanliness and bacterial contamination of equipment used to harvest and feed colostrum on 8 French dairy farms. The study was conducted in 2 phases: before (phase 1) and after (phase 2) the implementation of farm-specific recommendations. During each phase, equipment cleanliness (e.g., robot-compatible buckets, milking buckets, transfer buckets, bottles, nipples, nipple buckets, drenchers, and esophageal tube feeders [ET]) was assessed using ATP luminometry (through direct surface [ATP-S] and rinsing liquid [ATP-L] swabbing, expressed in relative light units [RLU]), visual scoring, and culture-based bacteriological analysis. Fresh colostrum samples were also collected and analyzed during each phase. A self-reported questionnaire administered during phase 1 identified critical control points for colostrum contamination, which informed the formulation of practical hygiene recommendations. Contamination thresholds were defined as ≥100,000 cfu/mL for total bacterial count (TBC) and ≥10,000 cfu/mL for total coliform count (TCC). Hygiene practices related to the operator, cow teats, and equipment varied considerably among farms, as did adherence to the recommended practices. Overall, lower RLU values were recorded on equipment surfaces during phase 2 compared with phase 1 (ATP-L: -1.51 log [±0.24], P < 0.001; ATP-S: -1.15 log [±0.24], P < 0.001). These reductions were associated with good operator hygiene practices and the use of brand-new equipment. Lower levels of contamination of colostrum samples were found in phase 2 (TBC: -0.92 log [±0.19], P < 0.001; TCC: -1.14 log [±0.30], P < 0.001), associated with good operator hygiene practices. Significant correlations (Spearman's rho, r<sub>s</sub>) were observed between visual cleanliness scores and RLU values from both swabbing techniques, as well as between ATP-L RLU values and bacterial counts (TBC: r<sub>s</sub> = 0.744, 95% CI: 0.556-0.859, P < 0.0001; TCC: r<sub>s</sub> = 0.475, 95% CI: 0.183-0.690, P < 0.002). Based on ATP-L swab results, optimal luminometry cutpoints maximizing (sensitivity + specificity) were identified at ≥6,950 RLU (sensitivity: 79.17%; specificity: 100%) for TBC, and ≥11,912 RLU (sensitivity: 88.89%; specificity: 70.97%) for TCC. 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Monitoring colostrum harvesting and distribution equipment cleanliness with ATP luminometry before and after recommendations to improve hygiene practices in French dairy farms.
This observational study evaluated the effects of practical hygiene recommendations on cleanliness and bacterial contamination of equipment used to harvest and feed colostrum on 8 French dairy farms. The study was conducted in 2 phases: before (phase 1) and after (phase 2) the implementation of farm-specific recommendations. During each phase, equipment cleanliness (e.g., robot-compatible buckets, milking buckets, transfer buckets, bottles, nipples, nipple buckets, drenchers, and esophageal tube feeders [ET]) was assessed using ATP luminometry (through direct surface [ATP-S] and rinsing liquid [ATP-L] swabbing, expressed in relative light units [RLU]), visual scoring, and culture-based bacteriological analysis. Fresh colostrum samples were also collected and analyzed during each phase. A self-reported questionnaire administered during phase 1 identified critical control points for colostrum contamination, which informed the formulation of practical hygiene recommendations. Contamination thresholds were defined as ≥100,000 cfu/mL for total bacterial count (TBC) and ≥10,000 cfu/mL for total coliform count (TCC). Hygiene practices related to the operator, cow teats, and equipment varied considerably among farms, as did adherence to the recommended practices. Overall, lower RLU values were recorded on equipment surfaces during phase 2 compared with phase 1 (ATP-L: -1.51 log [±0.24], P < 0.001; ATP-S: -1.15 log [±0.24], P < 0.001). These reductions were associated with good operator hygiene practices and the use of brand-new equipment. Lower levels of contamination of colostrum samples were found in phase 2 (TBC: -0.92 log [±0.19], P < 0.001; TCC: -1.14 log [±0.30], P < 0.001), associated with good operator hygiene practices. Significant correlations (Spearman's rho, rs) were observed between visual cleanliness scores and RLU values from both swabbing techniques, as well as between ATP-L RLU values and bacterial counts (TBC: rs = 0.744, 95% CI: 0.556-0.859, P < 0.0001; TCC: rs = 0.475, 95% CI: 0.183-0.690, P < 0.002). Based on ATP-L swab results, optimal luminometry cutpoints maximizing (sensitivity + specificity) were identified at ≥6,950 RLU (sensitivity: 79.17%; specificity: 100%) for TBC, and ≥11,912 RLU (sensitivity: 88.89%; specificity: 70.97%) for TCC. This study demonstrates that targeted hygiene improvements can significantly reduce both equipment surface and colostrum bacterial contamination and support the use of ATP luminometry as a practical tool for hygiene monitoring on dairy farms.
期刊介绍:
The official journal of the American Dairy Science Association®, Journal of Dairy Science® (JDS) is the leading peer-reviewed general dairy research journal in the world. JDS readers represent education, industry, and government agencies in more than 70 countries with interests in biochemistry, breeding, economics, engineering, environment, food science, genetics, microbiology, nutrition, pathology, physiology, processing, public health, quality assurance, and sanitation.