Prediction of health disorders in dairy cows monitored with collar based on Binary logistic analysis

Zhou, Xiaojing; Xu, Chuang; Zhao, Zixuan; Wang, Hao; Chen, Mengxing; Jia, Bin

doi:10.1590/1678-4162-12880

ABSTRACT

The objective of this study was to analyze data on physical activity and rumination time monitored via collars at the farm coupled with milk yield recorded by the rotary milking system to predict cows based on several disorders using the binary Logistic regression conducted with R software. Data for metritis (n=60), mastitis (n=98), lameness (n=35), and digestive disorders (n=52) were collected from 1,618 healthy cows used to construct the prediction model. To verify the feasibility and adaptability of the proposed method, we analyzed data of cows in the same herd (herd 1) not used to construct the model, and cows in another herd (herd 2) with data recorded by the same type of automated system, and led to detection of 75.0%, 64.2%, 74.2%, and 76.9% animals in herd 1 correctly predicted to suffer from metritis, mastitis, lameness, and digestive disorders, respectively. For cows in herd 2, 66.6%, 58.8%, 80.7%, and 71.4% were correctly predicted for metritis, mastitis, lameness, and digestive disorders, respectively. Compared with traditional clinical diagnoses by farm personnel, the algorithm developed allowed for earlier prediction of cows with a disorder.

Keywords:
disorders; binary logistic regression; prediction; rumination; activity; milk yield

RESUMO

Os objetivos deste estudo foram analisar dados sobre a atividade física e o tempo de ruminação monitorados através de coleiras na fazenda junto com a produção de leite registrada pelo sistema rotativo de ordenha para prever vacas com base em vários distúrbios utilizando o software de regressão logística binária realizado com o software R. Dados para metrite (n=60), mastite (n=98), manqueira (n=35) e distúrbios digestivos (n=52) foram coletados de 1.618 vacas saudáveis foram usados para construir o modelo de previsão. Para verificar a viabilidade e adaptabilidade do método proposto, analisamos os dados de vacas do mesmo rebanho (rebanho 1) não utilizadas para construir o modelo, e vacas de outro rebanho (rebanho 2) com dados registrados pelo mesmo tipo de sistema automatizado, e levamos à detecção de 75,0%, 64,2%, 74,2%, e 76,9% de animais do rebanho 1 previstos corretamente para sofrer de metrite, mastite, manqueira e distúrbios digestivos, respectivamente. Para as vacas do rebanho 2, 66,6%, 58,8%, 80,7% e 71,4% foram previstos corretamente para metrite, mastite, manqueira e distúrbios digestivos, respectivamente. Em comparação com os diagnósticos clínicos tradicionais feitos pelo pessoal da fazenda, o algoritmo desenvolvido permitiu a previsão antecipada de vacas com um distúrbio.

Palavras-chave:
desordens; regressão logística binária; predição; ruminação; atividade; produção de leite

INTRODUCTION

Automatic monitoring has been applied across many intensive dairy farm systems worldwide, where large amounts of data on rumination time, physical activity, and feeding behavior, among others, have been collected. These data are often coupled with milk yield-related variables monitored by automated milking systems. Some common disorders of dairy cows in intensive farms, such as mastitis, metritis, subclinical ketosis, lameness, et al., are detrimental to cow well-being and farm profitability because they cause losses in milk production (Edwards and Tozer, 2004EDWARDS, J.L.; TOZER, P.R. Using activity and milk yield as predictors of fresh cow disorders. J. Dairy Sci., v.87, p.524-531, 2004., Stangaferro et al., 2016aSTANGAFERRO, M.L.; WIJMA, R.; CAIXETA, L.S.; AL-ABRI, M.A.; GIORDANO, J.O. Use of rumination and activity monitoring for the identification of dairy cows with health disorders: Part 1. Metabolic and digestive disorders. J. Dairy Sci., v.99, p.7395-7410, 2016a.), increase the risk of culling and death (King et al., 2018KING, M.T.M.; LEBLANC, S.J.; PAJOR, E.A.; WRIGHT, T.C.; DEVRIES, T.J. Behavior and productivity of cows milked in automated systems before diagnosis of health disorders in early lactation. J. Dairy Sci., v.101, p.4343-4356, 2018., Seifiet et al., 2011SEIFIET, H.A.; LEBLANC, S.J.; LESLIE, K.E.; DUFFIELD, T.F. Metabolic predictors of post-partum disease and culling risk in dairy cattle. Vet. J., v.188, p.216-220, 2011.), increase treatment costs (Stangaferro 2016b), and impair reproductive performance (Ribeiro, 2013RIBEIRO, E.S.; LIMA, L.F.; GRECO, L.F. et al. Prevalence of periparturient diseases and effects on fertility of seasonally calving grazing dairy cows supplemented with concentrates. J. Dairy Sci., v.96, p.5682-5697, 2013., Vercouteren et al., 2015VERCOUTEREN, M.M.; BITTAR, J.H.; PINEDO, P.J. et al. Factors associated with early cyclicity in postpartum dairy cows. J. Dairy Sci., v.98, p.229-239, 2015.). Health disorders can greatly affect the welfare of dairy cows, for the affected cows often experience severe pains (Stojkov, 2015STOJKOV, J.; VON KEYSERLINGK, M.A.G.; MARCHANT-FORDE, J.N.; WEARY, D.M. Assessment of visceral pain associated with metritis in dairy cows. J. Dairy Sci., v.98, v.5352-5361, 2015.). However, due to the farmers’ awareness of early prediction for health disorders and the measures of detection, most subclinical diseases go undiagnosed, making treatment difficult and prolonging any negative effects on herd health and productivity. Thus, data preceding diagnoses would be inherently more useful for earlier diagnoses and intervention if they can predict risk or detect disease more efficiently than the observation of clinical signs. Many studies conducted in several countries have reported that commercial dairy farms have adopted precision dairy technologies to monitor the prevalence and risk factors involved with health disorders (King et al., 2018, Overton et al., 2017OVERTON, T.R.; MCART, J.A.A.; NYDAM, D.V. A 100-Year Review: Metabolic health indicators and management of dairy cattle. J. Dairy Sci., v.100, p.10398-10417, 2017., Ruegg, 2017RUEGG, P.L. A 100-Year Review: Mastitis detection, management, and prevention. J. Dairy Sci., v.100, p.10381-10397, 2017., Sjöström et al., 2018SJÖSTRÖM, K.; FALL, N.; BLANCO-PENEDO, I.; DUVAL, J.E.; KRIEGER, M.; EMANUELSON, U. Lameness prevalence and risk factors in organic dairy herds in four European countries. Livest. Sci., v.208, p.44-50, 2018.). Furthermore, some potential indicators to identify cows with several common health problems have been discussed (Rutten et al., 2013RUTTEN, C.J.; VELTHUIS, A.G.J.; STEENEVELD, W.; HOGEVEEN, H. Invited review: Sensors to support health management on dairy farms. J. Dairy Sci., v.96, p.1928-1952, 2013.) including milk and milk yield-related factors, and physical activity and rumination time. Daily milk production and physical activity data followed obvious patterns before 21 days and up to 7 days after diagnosis of several health disorders, such as mastitis, metritis, subclinical ketosis, et al. (Gröhn et al., 1998GRÖHN, Y.T.; EICKER, S.W.; DUCROCQ, V.; HERTL, J.A. Effect of diseases on the culling of Holstein dairy cows in New York State. J. Dairy Sci., v.81, p.966-978, 1998.). Rumination time has been shown to decline with the onset of many health disorders such as mastitis (Fogsgaard et al., 2015FOGSGAARD, K.K.; BENNEDSGAARD, T.W.; HERSKIN, M.S. Behavioral changes in freestall-housed dairy cows with naturally occurring clinical mastitis. J. Dairy Sci., v.98, p.1730-1738, 2015., Soriani et al., 2012SORIANI, N.; TREVISI, E.; CALAMARI, L. Relationships between rumination time, metabolic conditions, and health status in dairy cows during the transition period. J. Anim. Sci., v.90, p.4544-4554, 2012.), metritis and pneumonia, metabolic disorders (Stangaferro et al., 2016a, 2016b, 2016c), subclinical ketosis (SCK), and retained placenta (Liboreiro et al., 2015LIBOREIRO, D.N.; MACHADO, K.S.; SILVA, P.R. et al. Characterization of peripartum rumination and activity of cows diagnosed with metabolic and uterine diseases. J. Dairy Sci., v.98, p.6812-6827, 2015.). With the increasing demand for health and welfare monitoring in modern dairy farming, observations of physiologic and behavioral changes should be considered thoroughly when monitoring for health disorders.

The main approach for predicting and/or detecting disorders of cows in intensive dairy farms in Northeast China still relies on traditional approaches, i.e., the manual observation by herd veterinarians and farm staff. Most of these farms have adopted precision dairy technologies mainly to identify cow estrus-related events, while most functions of these technologies are not utilized at all. To our best knowledge, there has been no attempt to use data of physical activity and rumination time recorded by precision dairy technologies to monitor health in these intensive dairy farms in Northeast China, neither the early warning of dairy cows’ health disorders by integrating these big data generated everyday by the automated monitoring system.

Our general hypothesis was that naturally occurring health disorders of cows in two herds monitored via collar and milked by rotary milking system were associated with physical activity, rumination time and milk yield. To address this hypothesis, the objective was to construct a prediction model using binary logistic regression of metritis, mastitis, lameness (digital dermatitis, interdigital dermatitis, sole ulcers, and abscesses), and digestive disorders (ruminal indigestion, forestomach retardation, and ruminal flatulence) data as categorical variables to determine which kind of disorder a cow was most likely suffering from. The prediction model was tested and verified at 2 commercial farms.

MATERIALS AND METHODS

This research was part of a large study aimed at early prediction and detection of health disorders of cows in commercial herds milked with rotary milking system and worn collar monitoring rumination in the intensive dairy farms in Northeast China. Holstein cows with the days in milk (DIM) in the whole lactation were included.

The original data were collected from two commercial farms near each other in the Heilongjiang province in Northeast China from January 2020 to March 2021. The two herds had a total of 3,678 Holstein cows, with herd 1 containing a total of 2,674 cows and herd 2 a total of 1,004 cows. Heilongjiang province is at longitude 121.11 and 135.05, latitude 43.26 and 53.33, with cold temperate zone and temperate continental monsoon climate, and the annual average temperature between -5 °C to 5 °C. These two farms are the practice base of Heilongjiang Bayi Agricultural University. Each evaluated group was housed in uniform pens with identical characteristics: enclosed barns on concrete solid floor with sawdust with space for 50 to 136 cows by providing the same cubicles, feeding and water area in each pen, feed bunk and access to an exercise yard for 1 h/d except in winter. Barns were naturally ventilated and with spraying used for control of heat stress in summer with an interval every 20 m. Cows were fed a total mixed ration (TMR) twice daily (0500 h and 1300 h) with ad libitum access to fresh water, milked three times daily (0500h, 1300h and 2100h). Before calving, cows had ad libitum access to a prepartum TMR containing a dietary forage-to-concentrate ratio of 78:22 on a dry matter (DM) basis. After calving, the TMR had a 60:40 forage-to-concentrate ratio on a DM basis. Overall, management routines and feeding practices were similar between the analyzed herds.

From 1 DIM to the end of lactation, primiparous and multiparous cows were fed the same TMR. Except when a warning event was given by the automated monitoring system adopted by the farms, cows were checked daily for signs of disease or injury by the farm staff, as well as reproductive events and survival, and health assessments were routinely performed during the transition period. All cases of health problems, diagnoses and treatments were recorded by the farm manager and the herd veterinarian according to standard operating procedures of the farm. During data editing, the following criteria were used to remove records from the final data set: parameters monitored by the precision dairy technologies without data; cows with missing data 21 days before time of diagnosis in a group; and cows that were moved between herds more than twice within a lactation. Milk yield, physical activity and rumination time of healthy and sick cows were analyzed. These variables would begin to deviate from normal at 3 days to 7 days or even more before diagnosis, and the response could vary based on the type of disorder. The null hypothesis was that such variables would not deviate before diagnosis and thus, not aid in detection. To test the hypothesis of herd 1, we first used binary logistic analysis to develop a model using individual cow data with health disorders collected 7 days (d-7) or 3 days (d-3) before diagnosis to 1 day before (d-1) diagnosis.

Veterinarians at the two farms diagnosed disorders based on a set of standard diagnostic procedures. Cases of metritis were identified by foul-smelling vulvar discharge and a rectal temperature ≥39.5°C in cows at 1d, 3d, 5d, 7d, 10d, 14d, 21d after calving, examined by the veterinarians of the farms. An examination of the udder and milk for clinical signs of mastitis (i.e., hard quarter, heat or swelling, clots in milk, flakes, clots, or lumps, or clear/yellow milk) was performed every 3 d after calving until d +21, then checked every 7 d throughout the whole lactation, here, due to no milk harvest for the cows at the transition period, hence, animals in this period were not involved in the analysis. Cases of lameness including digital dermatitis, interdigital dermatitis, sole ulcers, and abscesses, were diagnosed when mechanical or infectious lesions were detected by veterinarians or during routine half-month hoof trimming and treated with corrective hoof trims. For digestive disorders, scant manure, and lack of appetite with ruminal and intestinal stasis, including ruminal indigestion, forestomach retardation, and ruminal flatulence. A healthy cow was one that did not have an occurrence of any disorder studied during the experimental period, and we did not consider the cows that were sick more than once during lactation. For the assessment of herd 1, a total of 1,618 healthy cows and cows with metritis (n=60), mastitis (n=98), lameness (n=35) and digestive disorders (n=52) were analyzed by the proposed prediction model. For the assessment of herd 2, a total of 819 healthy cows with metritis (n=30), mastitis (n=68), lameness (n=52) and digestive disorders (n=53) were enrolled.

Data on physical activity recorded with the HR-Tag monitoring system (SCR Engineers Ltd., Netanya, Israel) and rumination time recorded with the neck collar (Nedap Livestock Management, Groenlo, Netherlands) were averaged and stored at 2-h intervals up to 24 h. Total rumination minutes per day were used for statistical analysis unless otherwise stated. The automatic monitoring system records daily activity from a pedometer attached to a leg band on the hind leg of the cow. Activity was recorded as a unitless measure of upward vertical head and neck movements such as walking and mounting while excluding downward vertical and horizontal movements such as feeding and recorded every 2 h. Rumination time of each dairy cow was also recorded every 2 h. Cows at each farm were milked three times a day (0500 h, 1300 h and 2100 h) via rotary milking system (FreeFlow, SCR Engineers Ltd., Netanya, Israel) with 64 or 72 individuals. All data were transferred automatically during each milking to the herd management software (DataFlow, SCR Engineers Ltd.) and daily milk yield was calculated as the sum of all milk collected per cow per day.

Cows were first grouped into various health disorder categories, with the day of diagnosis and treatment of each disorder considered as d 0, and the data for every variable from d-7 to d-1 was considered in the model: total activity, milk yield and rumination time per day. These were used for statistical analysis unless otherwise stated. Cows were included in an illness category only if they were affected with a particular disorder. Cows in the “healthy” category did not suffer from any disorders during the experiment.

In this study, we adopted the widely applied binary logistic regression for prediction and detection of onset of dairy cows’ disorders (Gianola et al., 2011GIANOLA, D.; OKUT, H.; WEIGEL, K.A.; ROSA, G.J. Predicting complex quantitative traits with Bayesian neural networks: A case study with Jersey cows and wheat. BMC Genet., v.12, p.87, 2011.). Prior to analyses, all data were screened for normality, and the predictor variable of each health disorder and the corresponding health group was conducted significance test, when there was significant difference between the health group and control group, the predicting model was constructed to recognize the cows with health disorders from all the analyzed cows by binary logistic carried out with the program written by software R 4.1.2.

We assessed the performance of each prediction model by their sensitivity, specificity, accuracy, precision, F1-score, and area under the receiver operating characteristic (ROC) curve (AUC) value (95% confidence interval) was defined as follows:

S e n s i t i v i t y = \frac{T P}{T P + F N}, S p e c i f i c i t y = \frac{T N}{T N + F P}, A c c u r a c y = \frac{T P + T N}{T P + T N + F P + F N},

\Pr e c i s i o n = \frac{T P}{T P + F P}, F 1 - s c o r e = \frac{2 * \Pr e c i s i o n * S e n s i t i v i t y}{\Pr e c i s i o n + S e n s i t i v i t y}

True positives (the number of cows with actual health disorder, predicted as with disorder), false negatives (the number of cows with actual health disorder, predicted as healthy), true negatives (the number of healthy cows, predicted as healthy), and false positives (the number of healthy cows, predicted as with health disorder) were denoted as TP, FN, TN, and FP, respectively.

RESULTS AND DISCUSSION

The Chi-square test and t-test function in R software were adopted to perform significant tests for categorical outcomes and continuous variables between each health disorder group and the corresponding healthy group. The time from 7 days before diagnosis to the day of diagnosis is recorded as d-7, d-6, d-5, d-4, d-3, d-2, d-1, and d0, respectively. The t-test showed that activity, rumination time, and milk production in more than four days of these 7 days was significantly (P<0.001) lower or higher than that of d0. To avoid overfitting caused by too many variables, new features related to milk yield, activity and rumination time were constructed as the independent variable of the regression model.

Considering that the milk production decreased averagely to 21.4±3.24kg/d on d-5, d-4, d-3, the average of these three days was recorded as m1_3. The mean milk yield of d-2 and d-1 dropped to 19.6±2.89kg/d, and the average of these two days was recorded as m1₂. Activity on d-4, d-3 and d-2 decreased to an average of 352±89 (unitless), and was negatively related to metritis, which was denoted as a1₃, and activity on d-1 denoted as a1_-1. The average rumination time on d-4, d-3 and d-2 was also negatively correlated to metritis and denoted as r1₃, average of d-1denoted as r1_-1. Likewise, the data of the corresponding healthy cows was denoted as the ones of disorders. These six variables were taken as independents to construct the Logistic prediction model as follows

Z = 3.807 - 0.096 m 1_{3} - 0.235 m 1_{2} - 0.012 a 1_{3} - 0.218 a 1_{- 1} - 0.005 r 1_{3} - 0.013 r 1_{- 1}

Where, standard deviations of intercept, m1₃, m1₂, a1₃, a1_-1, r1₃, r1_-1 were 0.123, 0.096, 0.101, 0.006, 0.080, 0.005 and 0.007, respectively.

Considering that the average milk production was 33±4.5kg/d on d-7, d-6, d-5, the average of these three days was recorded as m2_3. The mean milk yield of d-4 to d-3 increased to 32±3.01kg/d, and the average of these two days was recorded as m2₂; the average milk yield on d-1 denoted as m2_-1, m₀ for d0. Activity on d-3, d-2 and d-1 decreased to 464 ±93(unitless), and the average of these three days was negatively related to mastitis, which was denoted as a₃. The average rumination time on d-3, d-2 and d-1 was also negatively correlated to mastitis and denoted as r2₃, rumination time on d-1 and d0 denoted as r2_-1, r2₀. Likewise, the data of the corresponding health cows was denoted as the ones of disorders. Take these six variables as independents to construct the logistic prediction model as follows

Z = 2.200 + 0.105 m 2_{3} + 0.144 m 2_{2} - 0.380 m 2_{- 1} - 0.006 a 2_{3} + 0.015 r 2_{3} + 0.009 r 2_{- 1}

Where, standard deviations of intercept, m2₃, m2₂, m2_-1, a2₃, r12₃, r2_-1 were 0.890, 0.059, 0.066, 0.551, 0.003, 0.003 and 0.003, respectively.

Milk yield, activity and rumination time of digestive disorder only presented significant difference from d-3, d-2 or d-1 to d0, and the involved variables including milk yield on d-2, activity on d-1, rumination time on d-3, d-2, d-1, and with the lowest value of 28 ±1.98kg/d for milk yield on d-2, 432±97 (unitless) for activity on d-1, 387±85 min/d for rumination time on d-1. These seven variables were taken as independents to construct the Logistic prediction model as follows

Z = 17.117 - 0.069 m 3_{- 2} + 0.001 a 3_{- 1} - 0.186 r 3_{- 3} - 0.007 r 3_{- 2} - 0.023 r 3 -_{1}

Where, standard deviations of intercept, m3_-2, a3_-1, r3_-3, r3_-2, r3-₁ were 0.096, 0.123, 0.006, 0.080, 0.005 and 0.007, respectively.

Lameness was a chronic disorder, rumination time and milk yield did not present clear variance, while activity was definitely below the control group on d-4 to d0.

Milk yield on d-7 to d-1 was not significantly less or more than that on d0, hence variable related to milk yield was not involved in the prediction model. Activity on d-7, d-6 and d-5 increased to average of 552 ±102 (unitless), and was positively related to lameness, which was denoted as a4₃, and activity on d-4 and d-3 negatively correlated with this disorder and the average milk yield of these two days denoted as a4₂, likewise, the average milk yield on d-2 denoted as a4_-2 and a4_-1 on d-1. The average of rumination time on d-3, d-2 was also negatively correlated to lameness and average of these two days denoted as r4₂, denoted as r4_-1 on d-1. Likewise, the data of the corresponding health cows was denoted as the ones of disorders. These six variables were taken as independents to construct the logistic prediction model for lameness as follows

Z = 3.807 + 0.096 a 4_{3} + 0.235 a 4_{2} - 0.012 a 4_{- 2} - 0.218 a 4_{- 1} - 0.005 r 4_{2} - 0.013 r 4_{- 1}

Where, standard deviations of intercept, m4_-2, a4_-1, r4_-3, r4_-2, r4-₁ were 0.131, 0.027, 0.140, 0.005, 0.0004, 0.034, 0.0001, and 0.056, respectively.

Performance for four prediction models was summarized in Table 1. Specificity of four models were more than 95%, with the highest of 99.19 for cows with metritis. While the specificity was relatively lower, indicating that more than 25% of cows with disorders were not successfully predicted.

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Table 1
Performance evaluation of prediction model for metritis, mastitis, lameness, digestive disorder

Using the prediction model established by the data from farm 1 to predict sick cows not used for constructing models (Table 2) resulted in a slightly lower detection percentage for each disorder. Seventy-five percent of the cows identified by the model for predicting metritis one day before diagnosis were suffering with metritis, 13.3% were suffering with mastitis, 8.3% with a hoof disorder, and 3.3% with a digestion disorder. Using the prediction model established by the data of farm 1 to detect sick cows in farm 2 also presented a lower detection percentage for each disorder, see Table 3. Only 58.82% of detection percentage for metritis, while 16.67% were detected to suffer mastitis, demonstrated the instability of the prediction model.

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Table 2
Detection percentage of cows with disorders in farm 1 at different times using the prediction model established by data of farm 1

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Table 3
Detection percentage of disorders in cows from farm 2 using discriminate function established by data from farm 1

Researchers have previously examined associations between changes in rumination, activity, and milk yield data with health disorders (Andrés et al., 2018ANDRÉS, S..; TOM, V.; EDDIE, A.M. et al. Performance of human observers and an automatic 3-dimensional computer-vision-based locomotion scoring method to detect lameness and hoof lesions in dairy cows. J. Dairy Sci., v.101, p.6322-6335, 2018., Fogsgaard et al., 2015FOGSGAARD, K.K.; BENNEDSGAARD, T.W.; HERSKIN, M.S. Behavioral changes in freestall-housed dairy cows with naturally occurring clinical mastitis. J. Dairy Sci., v.98, p.1730-1738, 2015., Hertem et al., 2013HERTEM, VAN T.; MALTZ, E.; ANTLER, A. et al. Lameness detection based on multivariate continuous sensing of milk yield, rumination, and neck activity. J. Dairy Sci., v.96, p.4286-4298, 2013., King et al., 2017KING, M.T.M.; DANCY, K.M.; LEBLANC, S.J.; PAJOR, E.A.; DEVRIES, T.J. Deviations in behavior and productivity data before diagnosis of health disorders in cows milked with an automated system. J. Dairy Sci., v.100, p.8358-8371, 2017., 2018, Schirmann et al., 2016SCHIRMANN, K.; WEARY, D.M.; HEUWIESER, W. et al. Short communication: Rumination and feeding behaviors differ between healthy and sick dairy cows during the transition period. J. Dairy Sci., v.99, p.9917-9924, 2016., Tsai et al., 2021TSAI, I.C.; MAYO L.M.; BEWLEY J.M. Precision dairy monitoring technologies use indisease detection: differences in behavioral and physiological variables measured with precision dairy monitoring technologies between cows with or without metritis, hyperketonemia, and hypocalcemia. Livest. Sci., v.244, p.104334, 2021.) and detection of clinical disease, with a focus on post-partum subclinical ketosis (Rodriguez et al., 2018, Raboisson et al., 2014RABOISSON, D.; MOUNIÉ, M.; MAIGNÉ, E. Diseases, reproductive performance, and changes in milk production associated with subclinical ketosis in dairy cows: A meta-analysis and review. J. Dairy Sci., v.97, p.7547-7563, 2014.), lameness and hoof lesions (Kamphuis et al., 2013KAMPHUIS, C.; FRANK, E.; BURKE, J.K.; VERKERK, G.A.; JAGO, J.G. Applying additive logistic regression to data derived from sensors monitoring behavioral and physiological characteristics of dairy cows to detect lameness. J. Dairy Sci., v.96, p.7043-7053, 2013., Weigele et al., 2018WEIGELE, H.C.; GYGAX, L.; STEINER, A.; WECHSLER, B.; BURLA, J.B. Moderate lameness leads to marked behavioral changes in dairy cows. J. Dairy Sci., v.101, p.2370-2382, 2018.), mastitis (Stangaferro et al., 2016bSTANGAFERRO, M.L.; WIJMA, R.; CAIXETA, L.S.; AL-ABRI, M.A.; GIORDANO, J.O. Use of rumination and activity monitoring for the identification of dairy cows with health disorders:Part 2. Mastitis. J. Dairy Sci., v.99, p.7411-7421, 2016b., Zhang et al., 2020ZHANG, X.D.; KANG, X.; FENG, N.N.; LIU, G. Automatic recognition of dairy cow mastitis from thermal images by a deep learning detector. Comput. Electr. Agric., v.178, p.105754, 2020.), metritis, hyperketonemia and hypocalcemia (Ricardo 2020RICARDO, C.C. Predicting the risk of retained fetal membranes and metritis in dairy cows according to prepartum hemogram and immune and metabolic status. Prev. Vet. Med., v.187, p.105204, 2020., Stangaferro et al., 2016c, Tsai et al., 2021).

Kamphuis et al. (2013KAMPHUIS, C.; FRANK, E.; BURKE, J.K.; VERKERK, G.A.; JAGO, J.G. Applying additive logistic regression to data derived from sensors monitoring behavioral and physiological characteristics of dairy cows to detect lameness. J. Dairy Sci., v.96, p.7043-7053, 2013.) proposed applying additive logistic regression to data derived from sensors monitoring behavioral and physiological characteristics of dairy cows for lameness detection. Seven variables of milk yield, live-weight and activity were treated as significant factors without considering rumination time. Stangaferro et al. 2016aSTANGAFERRO, M.L.; WIJMA, R.; CAIXETA, L.S.; AL-ABRI, M.A.; GIORDANO, J.O. Use of rumination and activity monitoring for the identification of dairy cows with health disorders: Part 1. Metabolic and digestive disorders. J. Dairy Sci., v.99, p.7395-7410, 2016a., 2016b, 2016c) used rumination and activity monitoring for identification of dairy cows with health disorders including metabolic and digestive disorders, metritis, mastitis caused by E. coli, with sick cows chosen from d-21 to 80 d in milk. In the present study, however, all health disorders recorded for cows at any time during the whole lactation were considered. King et al. (2017KING, M.T.M.; DANCY, K.M.; LEBLANC, S.J.; PAJOR, E.A.; DEVRIES, T.J. Deviations in behavior and productivity data before diagnosis of health disorders in cows milked with an automated system. J. Dairy Sci., v.100, p.8358-8371, 2017.) explored longitudinal changes in behavior and production data before diagnosis of health disorders in cows milked with an automated system. In that study, data of only 57 dairy cows with SCK, metritis, lameness, displaced abomasum, and pneumonia were analyzed, and the baseline time up to d-14, daily rumination time, body weight, milk temperature, activity were focused on while no prediction was mentioned.

A decrease in daily walking activity and rumination time, along with a decrease in milk yield, might be used as an early warning to identify potential disorders in dairy cattle. Several studies have created and validated such prediction models (Kandeel et al., 2019KANDEEL, S.A.; MEGAHED, A.A.; EBEID, M.H.; CONSTABLE, P.D. (2019). Ability of milk pH to predict subclinical mastitis and intramammary infection in quarters from lactating dairy cattle. J. Dairy Sci., v.102, p.1417-1427, 2019., Wisnieski et al., 2019WISNIESKI, L.; NORBY, B.; PIERCE, S.J. et al. Predictive models for early lactation diseases in transition dairy cattle at dry-off. Prev. Vet. Med., v.163, p.68-78, 2019., Xu et al., 2019XU, W.; VAN KNEGSEL, A.T.M.; VERVOORT, J.J.M. et al. Prediction of metabolic status of dairy cows in early lactation with on-farm cow data and machine learning algorithms. J. Dairy Sci., v.102, p.10186-10201, 2019., 2020). As early as 2004, Edwards and Tozer (2004EDWARDS, J.L.; TOZER, P.R. Using activity and milk yield as predictors of fresh cow disorders. J. Dairy Sci., v.87, p.524-531, 2004.) proposed that cows with metabolic, and general digestive disorders, could potentially be identified 5 to 6 d earlier than clinical diagnoses based on changes in daily walking. Early identification of cows at risk of developing those disorders could allow for timely intervention, potentially decreasing the negative effects of this disease. As mentioned above, there is much evidence indicating that health disorders in dairy cattle can be identified and predicted through observation of milk yield, physical activity, and changes in rumination time. In contrast, there is a severe paucity of data on the use of behavior, rumination time and productivity data for early detection of health issues in intensive dairy farms in Northeast China. The fact that these farms have widely adopted the use of automated systems underscores the potential benefit of using the data as a predictive tool. Although the present results offer a promising outlook, translating the results into practice based on the current sensor-based variables that only encompassed simple proportional differences also highlighted that prediction success was somewhat modest for implementation in larger intensified dairy farms. By developing variables that better describe changes in sensor data patterns from a greater number of factors affecting health, we believe that future research may improve detection performance with the aid of artificial intelligence. This also would extend to prediction of health disorders in calves that are being monitored by automatic systems.

CONCLUSIONS

In modern intensive dairy farms, developing valid, reliable, and practical automated disease detection systems has always been a central issue in veterinary practice. Automated rumination and activity monitoring was effective for identifying cows afflicted with several health disorders. Overall, according to these results, milk yield, physical activity and rumination time can be used for early or automated identification of several disorders. Thus, using these factors to develop software for detecting disorders may be of critical importance for improving animal welfare and increasing the economic benefits at the farm. Future research should focus on applying artificial intelligence to develop algorithms to diagnose disorders in lactating cows and calves more accurately and precisely.

ACKNOWLEDGMENTS

Heilongjiang Province Applied Technology Research and Development Program (Heilongjiang, China; grant no. GA20B201) supported this project.

All data, models, and code generated or used during the study appearing in the submitted article will be made available upon request to the corresponding author.

The study design was approved by the appropriate ethics review board. All animal procedures were performed in accordance with the Guidelines for the Care and Use of Experimental Animals in Heilongjiang Bayi Agricultural University (Daqing, China). The Animal Ethics Committee of Heilongjiang Bayi Agricultural University approved the study protocol (FBD201603006).

REFERENCES

ANDRÉS, S..; TOM, V.; EDDIE, A.M. et al. Performance of human observers and an automatic 3-dimensional computer-vision-based locomotion scoring method to detect lameness and hoof lesions in dairy cows. J. Dairy Sci., v.101, p.6322-6335, 2018.
EDWARDS, J.L.; TOZER, P.R. Using activity and milk yield as predictors of fresh cow disorders. J. Dairy Sci., v.87, p.524-531, 2004.
FOGSGAARD, K.K.; BENNEDSGAARD, T.W.; HERSKIN, M.S. Behavioral changes in freestall-housed dairy cows with naturally occurring clinical mastitis. J. Dairy Sci., v.98, p.1730-1738, 2015.
GIANOLA, D.; OKUT, H.; WEIGEL, K.A.; ROSA, G.J. Predicting complex quantitative traits with Bayesian neural networks: A case study with Jersey cows and wheat. BMC Genet., v.12, p.87, 2011.
GRÖHN, Y.T.; EICKER, S.W.; DUCROCQ, V.; HERTL, J.A. Effect of diseases on the culling of Holstein dairy cows in New York State. J. Dairy Sci., v.81, p.966-978, 1998.
HERTEM, VAN T.; MALTZ, E.; ANTLER, A. et al. Lameness detection based on multivariate continuous sensing of milk yield, rumination, and neck activity. J. Dairy Sci., v.96, p.4286-4298, 2013.
KAMPHUIS, C.; FRANK, E.; BURKE, J.K.; VERKERK, G.A.; JAGO, J.G. Applying additive logistic regression to data derived from sensors monitoring behavioral and physiological characteristics of dairy cows to detect lameness. J. Dairy Sci., v.96, p.7043-7053, 2013.
KANDEEL, S.A.; MEGAHED, A.A.; EBEID, M.H.; CONSTABLE, P.D. (2019). Ability of milk pH to predict subclinical mastitis and intramammary infection in quarters from lactating dairy cattle. J. Dairy Sci., v.102, p.1417-1427, 2019.
KING, M.T.M.; DANCY, K.M.; LEBLANC, S.J.; PAJOR, E.A.; DEVRIES, T.J. Deviations in behavior and productivity data before diagnosis of health disorders in cows milked with an automated system. J. Dairy Sci., v.100, p.8358-8371, 2017.
KING, M.T.M.; LEBLANC, S.J.; PAJOR, E.A.; WRIGHT, T.C.; DEVRIES, T.J. Behavior and productivity of cows milked in automated systems before diagnosis of health disorders in early lactation. J. Dairy Sci., v.101, p.4343-4356, 2018.
LIBOREIRO, D.N.; MACHADO, K.S.; SILVA, P.R. et al. Characterization of peripartum rumination and activity of cows diagnosed with metabolic and uterine diseases. J. Dairy Sci., v.98, p.6812-6827, 2015.
OVERTON, T.R.; MCART, J.A.A.; NYDAM, D.V. A 100-Year Review: Metabolic health indicators and management of dairy cattle. J. Dairy Sci., v.100, p.10398-10417, 2017.
RABOISSON, D.; MOUNIÉ, M.; MAIGNÉ, E. Diseases, reproductive performance, and changes in milk production associated with subclinical ketosis in dairy cows: A meta-analysis and review. J. Dairy Sci., v.97, p.7547-7563, 2014.
RIBEIRO, E.S.; LIMA, L.F.; GRECO, L.F. et al. Prevalence of periparturient diseases and effects on fertility of seasonally calving grazing dairy cows supplemented with concentrates. J. Dairy Sci., v.96, p.5682-5697, 2013.
RICARDO, C.C. Predicting the risk of retained fetal membranes and metritis in dairy cows according to prepartum hemogram and immune and metabolic status. Prev. Vet. Med., v.187, p.105204, 2020.
RODRIGUEZ-JIMENEZ, S.; HAERR, K.J.; TREVISI, E. et al. Prepartal standing behavior as a parameter for early detection of postpartal subclinical ketosis associated with inflammation and liver function biomarkers in peripartal dairy cows. J. Dairy Sci., v.101, p.8224-8235, 2018.
RUEGG, P.L. A 100-Year Review: Mastitis detection, management, and prevention. J. Dairy Sci., v.100, p.10381-10397, 2017.
RUTTEN, C.J.; VELTHUIS, A.G.J.; STEENEVELD, W.; HOGEVEEN, H. Invited review: Sensors to support health management on dairy farms. J. Dairy Sci., v.96, p.1928-1952, 2013.
SCHIRMANN, K.; WEARY, D.M.; HEUWIESER, W. et al. Short communication: Rumination and feeding behaviors differ between healthy and sick dairy cows during the transition period. J. Dairy Sci., v.99, p.9917-9924, 2016.
SEIFIET, H.A.; LEBLANC, S.J.; LESLIE, K.E.; DUFFIELD, T.F. Metabolic predictors of post-partum disease and culling risk in dairy cattle. Vet. J., v.188, p.216-220, 2011.
SJÖSTRÖM, K.; FALL, N.; BLANCO-PENEDO, I.; DUVAL, J.E.; KRIEGER, M.; EMANUELSON, U. Lameness prevalence and risk factors in organic dairy herds in four European countries. Livest. Sci., v.208, p.44-50, 2018.
SORIANI, N.; TREVISI, E.; CALAMARI, L. Relationships between rumination time, metabolic conditions, and health status in dairy cows during the transition period. J. Anim. Sci., v.90, p.4544-4554, 2012.
STANGAFERRO, M.L.; WIJMA, R.; CAIXETA, L.S.; AL-ABRI, M.A.; GIORDANO, J.O. Use of rumination and activity monitoring for the identification of dairy cows with health disorders: Part 1. Metabolic and digestive disorders. J. Dairy Sci., v.99, p.7395-7410, 2016a.
STANGAFERRO, M.L.; WIJMA, R.; CAIXETA, L.S.; AL-ABRI, M.A.; GIORDANO, J.O. Use of rumination and activity monitoring for the identification of dairy cows with health disorders: Part 3. Metritis. J. Dairy Sci., v.99, p.7422-7433, 2016c.
STANGAFERRO, M.L.; WIJMA, R.; CAIXETA, L.S.; AL-ABRI, M.A.; GIORDANO, J.O. Use of rumination and activity monitoring for the identification of dairy cows with health disorders:Part 2. Mastitis. J. Dairy Sci., v.99, p.7411-7421, 2016b.
STOJKOV, J.; VON KEYSERLINGK, M.A.G.; MARCHANT-FORDE, J.N.; WEARY, D.M. Assessment of visceral pain associated with metritis in dairy cows. J. Dairy Sci., v.98, v.5352-5361, 2015.
TSAI, I.C.; MAYO L.M.; BEWLEY J.M. Precision dairy monitoring technologies use indisease detection: differences in behavioral and physiological variables measured with precision dairy monitoring technologies between cows with or without metritis, hyperketonemia, and hypocalcemia. Livest. Sci., v.244, p.104334, 2021.
VERCOUTEREN, M.M.; BITTAR, J.H.; PINEDO, P.J. et al. Factors associated with early cyclicity in postpartum dairy cows. J. Dairy Sci., v.98, p.229-239, 2015.
WEIGELE, H.C.; GYGAX, L.; STEINER, A.; WECHSLER, B.; BURLA, J.B. Moderate lameness leads to marked behavioral changes in dairy cows. J. Dairy Sci., v.101, p.2370-2382, 2018.
WISNIESKI, L.; NORBY, B.; PIERCE, S.J. et al. Predictive models for early lactation diseases in transition dairy cattle at dry-off. Prev. Vet. Med., v.163, p.68-78, 2019.
XU, W.; SACCENTI, E.; VERVOORT, J. et al. Short communication: prediction of hyperketonemia in dairy cows in early lactation using on-farm cow data and net energy intake by partial least square discriminant analysis. J. Dairy Sci., v.103, p.6576-6582, 2020.
XU, W.; VAN KNEGSEL, A.T.M.; VERVOORT, J.J.M. et al. Prediction of metabolic status of dairy cows in early lactation with on-farm cow data and machine learning algorithms. J. Dairy Sci., v.102, p.10186-10201, 2019.
ZHANG, X.D.; KANG, X.; FENG, N.N.; LIU, G. Automatic recognition of dairy cow mastitis from thermal images by a deep learning detector. Comput. Electr. Agric., v.178, p.105754, 2020.

Publication Dates

Publication in this collection
02 June 2023
Date of issue
May-Jun 2023

History

Received
03 Aug 2022
Accepted
09 Nov 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ANDRÉS, S..; TOM, V.; EDDIE, A.M. et al. Performance of human observers and an automatic 3-dimensional computer-vision-based locomotion scoring method to detect lameness and hoof lesions in dairy cows. J. Dairy Sci., v.101, p.6322-6335, 2018.

[2] EDWARDS, J.L.; TOZER, P.R. Using activity and milk yield as predictors of fresh cow disorders. J. Dairy Sci., v.87, p.524-531, 2004.

[3] FOGSGAARD, K.K.; BENNEDSGAARD, T.W.; HERSKIN, M.S. Behavioral changes in freestall-housed dairy cows with naturally occurring clinical mastitis. J. Dairy Sci., v.98, p.1730-1738, 2015.

[4] GIANOLA, D.; OKUT, H.; WEIGEL, K.A.; ROSA, G.J. Predicting complex quantitative traits with Bayesian neural networks: A case study with Jersey cows and wheat. BMC Genet., v.12, p.87, 2011.

[5] GRÖHN, Y.T.; EICKER, S.W.; DUCROCQ, V.; HERTL, J.A. Effect of diseases on the culling of Holstein dairy cows in New York State. J. Dairy Sci., v.81, p.966-978, 1998.

[6] HERTEM, VAN T.; MALTZ, E.; ANTLER, A. et al. Lameness detection based on multivariate continuous sensing of milk yield, rumination, and neck activity. J. Dairy Sci., v.96, p.4286-4298, 2013.

[7] KAMPHUIS, C.; FRANK, E.; BURKE, J.K.; VERKERK, G.A.; JAGO, J.G. Applying additive logistic regression to data derived from sensors monitoring behavioral and physiological characteristics of dairy cows to detect lameness. J. Dairy Sci., v.96, p.7043-7053, 2013.

[8] KANDEEL, S.A.; MEGAHED, A.A.; EBEID, M.H.; CONSTABLE, P.D. (2019). Ability of milk pH to predict subclinical mastitis and intramammary infection in quarters from lactating dairy cattle. J. Dairy Sci., v.102, p.1417-1427, 2019.

[9] KING, M.T.M.; DANCY, K.M.; LEBLANC, S.J.; PAJOR, E.A.; DEVRIES, T.J. Deviations in behavior and productivity data before diagnosis of health disorders in cows milked with an automated system. J. Dairy Sci., v.100, p.8358-8371, 2017.

[10] KING, M.T.M.; LEBLANC, S.J.; PAJOR, E.A.; WRIGHT, T.C.; DEVRIES, T.J. Behavior and productivity of cows milked in automated systems before diagnosis of health disorders in early lactation. J. Dairy Sci., v.101, p.4343-4356, 2018.

[11] LIBOREIRO, D.N.; MACHADO, K.S.; SILVA, P.R. et al. Characterization of peripartum rumination and activity of cows diagnosed with metabolic and uterine diseases. J. Dairy Sci., v.98, p.6812-6827, 2015.

[12] OVERTON, T.R.; MCART, J.A.A.; NYDAM, D.V. A 100-Year Review: Metabolic health indicators and management of dairy cattle. J. Dairy Sci., v.100, p.10398-10417, 2017.

[13] RABOISSON, D.; MOUNIÉ, M.; MAIGNÉ, E. Diseases, reproductive performance, and changes in milk production associated with subclinical ketosis in dairy cows: A meta-analysis and review. J. Dairy Sci., v.97, p.7547-7563, 2014.

[14] RIBEIRO, E.S.; LIMA, L.F.; GRECO, L.F. et al. Prevalence of periparturient diseases and effects on fertility of seasonally calving grazing dairy cows supplemented with concentrates. J. Dairy Sci., v.96, p.5682-5697, 2013.

[15] RICARDO, C.C. Predicting the risk of retained fetal membranes and metritis in dairy cows according to prepartum hemogram and immune and metabolic status. Prev. Vet. Med., v.187, p.105204, 2020.

[16] RODRIGUEZ-JIMENEZ, S.; HAERR, K.J.; TREVISI, E. et al. Prepartal standing behavior as a parameter for early detection of postpartal subclinical ketosis associated with inflammation and liver function biomarkers in peripartal dairy cows. J. Dairy Sci., v.101, p.8224-8235, 2018.

[17] RUEGG, P.L. A 100-Year Review: Mastitis detection, management, and prevention. J. Dairy Sci., v.100, p.10381-10397, 2017.

[18] RUTTEN, C.J.; VELTHUIS, A.G.J.; STEENEVELD, W.; HOGEVEEN, H. Invited review: Sensors to support health management on dairy farms. J. Dairy Sci., v.96, p.1928-1952, 2013.

[19] SCHIRMANN, K.; WEARY, D.M.; HEUWIESER, W. et al. Short communication: Rumination and feeding behaviors differ between healthy and sick dairy cows during the transition period. J. Dairy Sci., v.99, p.9917-9924, 2016.

[20] SEIFIET, H.A.; LEBLANC, S.J.; LESLIE, K.E.; DUFFIELD, T.F. Metabolic predictors of post-partum disease and culling risk in dairy cattle. Vet. J., v.188, p.216-220, 2011.

[21] SJÖSTRÖM, K.; FALL, N.; BLANCO-PENEDO, I.; DUVAL, J.E.; KRIEGER, M.; EMANUELSON, U. Lameness prevalence and risk factors in organic dairy herds in four European countries. Livest. Sci., v.208, p.44-50, 2018.

[22] SORIANI, N.; TREVISI, E.; CALAMARI, L. Relationships between rumination time, metabolic conditions, and health status in dairy cows during the transition period. J. Anim. Sci., v.90, p.4544-4554, 2012.

[23] STANGAFERRO, M.L.; WIJMA, R.; CAIXETA, L.S.; AL-ABRI, M.A.; GIORDANO, J.O. Use of rumination and activity monitoring for the identification of dairy cows with health disorders: Part 1. Metabolic and digestive disorders. J. Dairy Sci., v.99, p.7395-7410, 2016a.

[24] STANGAFERRO, M.L.; WIJMA, R.; CAIXETA, L.S.; AL-ABRI, M.A.; GIORDANO, J.O. Use of rumination and activity monitoring for the identification of dairy cows with health disorders: Part 3. Metritis. J. Dairy Sci., v.99, p.7422-7433, 2016c.

[25] STANGAFERRO, M.L.; WIJMA, R.; CAIXETA, L.S.; AL-ABRI, M.A.; GIORDANO, J.O. Use of rumination and activity monitoring for the identification of dairy cows with health disorders:Part 2. Mastitis. J. Dairy Sci., v.99, p.7411-7421, 2016b.

[26] STOJKOV, J.; VON KEYSERLINGK, M.A.G.; MARCHANT-FORDE, J.N.; WEARY, D.M. Assessment of visceral pain associated with metritis in dairy cows. J. Dairy Sci., v.98, v.5352-5361, 2015.

[27] TSAI, I.C.; MAYO L.M.; BEWLEY J.M. Precision dairy monitoring technologies use indisease detection: differences in behavioral and physiological variables measured with precision dairy monitoring technologies between cows with or without metritis, hyperketonemia, and hypocalcemia. Livest. Sci., v.244, p.104334, 2021.

[28] VERCOUTEREN, M.M.; BITTAR, J.H.; PINEDO, P.J. et al. Factors associated with early cyclicity in postpartum dairy cows. J. Dairy Sci., v.98, p.229-239, 2015.

[29] WEIGELE, H.C.; GYGAX, L.; STEINER, A.; WECHSLER, B.; BURLA, J.B. Moderate lameness leads to marked behavioral changes in dairy cows. J. Dairy Sci., v.101, p.2370-2382, 2018.

[30] WISNIESKI, L.; NORBY, B.; PIERCE, S.J. et al. Predictive models for early lactation diseases in transition dairy cattle at dry-off. Prev. Vet. Med., v.163, p.68-78, 2019.

[31] XU, W.; SACCENTI, E.; VERVOORT, J. et al. Short communication: prediction of hyperketonemia in dairy cows in early lactation using on-farm cow data and net energy intake by partial least square discriminant analysis. J. Dairy Sci., v.103, p.6576-6582, 2020.

[32] XU, W.; VAN KNEGSEL, A.T.M.; VERVOORT, J.J.M. et al. Prediction of metabolic status of dairy cows in early lactation with on-farm cow data and machine learning algorithms. J. Dairy Sci., v.102, p.10186-10201, 2019.

[33] ZHANG, X.D.; KANG, X.; FENG, N.N.; LIU, G. Automatic recognition of dairy cow mastitis from thermal images by a deep learning detector. Comput. Electr. Agric., v.178, p.105754, 2020.

Performance Disorders	Sensitivity	Specificity	Accuracy	Precision	F1-score	AUC
Metritis	0.6000	0.9919	0.9051	0.9545	0.7368	0.8799
Mastitis	0.6311	0.9702	0.8962	0.8553	0.7263	0.8786
Lameness	0.6316	0.9651	0.9048	0.8000	0.7058	0.9345
Digestive	0.7105	0.9680	0.9080	0.8710	0.7826	0.9360

	Metritis	Mastitis	Lameness	Digestion disorder
Prediction model of Metritis	75.00	13.33	8.33	3.33
Prediction model of Mastitis	9.18	64.29	12.24	14.29
Prediction model of Lameness	2.86	14.29	74.29	8.57
Prediction model of Digestion disorder	1.92	13.46	7.69	76.92

	Metritis	Mastitis	Lameness	Digestion disorder
Prediction model of Metritis	66.67	16.67	6.67	10.00
Prediction model of Mastitis	13.24	58.82	17.65	10.29
Prediction model of Lameness	3.85	11.54	80.77	3.85
Prediction model of Digestion disorder	5.71	14.29	8.57	71.43

Brasil

Brasil

Prediction of health disorders in dairy cows monitored with collar based on Binary logistic analysis

[Previsão de distúrbios de saúde em vacas leiteiras monitoradas com base em coleira sobre análise logística binária]

ABSTRACT

RESUMO

INTRODUCTION

MATERIALS AND METHODS

RESULTS AND DISCUSSION

CONCLUSIONS

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History