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Review: Behavioral signs of estrus and the potential of fully automated systems for detection of estrus in dairy cattle

Published online by Cambridge University Press:  15 August 2017

S. Reith*
Affiliation:
Department of Animal Breeding and Genetics, Justus Liebig University Giessen, Leihgesterner Weg 52, D-35392 Giessen, Germany
S. Hoy
Affiliation:
Department of Animal Breeding and Genetics, Justus Liebig University Giessen, Leihgesterner Weg 52, D-35392 Giessen, Germany
*

Abstract

Efficient detection of estrus is a permanent challenge for successful reproductive performance in dairy cattle. In this context, comprehensive knowledge of estrus-related behaviors is fundamental to achieve optimal estrus detection rates. This review was designed to identify the characteristics of behavioral estrus as a necessary basis for developing strategies and technologies to improve the reproductive management on dairy farms. The focus is on secondary symptoms of estrus (mounting, activity, aggressive and agonistic behaviors) which seem more indicative than standing behavior. The consequences of management, housing conditions and cow- and environmental-related factors impacting expression and detection of estrus as well as their relative importance are described in order to increase efficiency and accuracy of estrus detection. As traditional estrus detection via visual observation is time-consuming and ineffective, there has been a considerable advancement of detection aids during the last 10 years. By now, a number of fully automated technologies including pressure sensing systems, activity meters, video cameras, recordings of vocalization as well as measurements of body temperature and milk progesterone concentration are available. These systems differ in many aspects regarding sustainability and efficiency as keys to their adoption for farm use. As being most practical for estrus detection a high priority – according to the current research – is given to the detection based on sensor-supported activity monitoring, especially accelerometer systems. Due to differences in individual intensity and duration of estrus multivariate analysis can support herd managers in determining the onset of estrus. Actually, there is increasing interest in investigating the potential of combining data of activity monitoring and information of several other methods, which may lead to the best results concerning sensitivity and specificity of detection. Future improvements will likely require more multivariate detection by data and systems already existing on farms.

Type
Review Article
Copyright
© The Animal Consortium 2017 

Implications

Comprehensive detailed knowledge – considering cow-, environmental- and management-related factors – of behavioral signs of estrus is crucial for the refinement of (fully) automated technologies for identifying estrual cows. The primary focus is on activity monitoring to detect the significant increase in activity levels that occurs during proestrus. For further improvement of estrus detection there is increasing interest in studying the potential and the benefits of multivariate detection. A combination of activity monitoring and several other methods may lead to acceptable estrus detection rates and thus to optimize reproductive management in dairy farms.

Introduction

Detection of estrus is one of the most important factors impacting the reproductive efficiency in dairy cattle, especially in farms using artificial insemination (AI). Reproduction management directly affects the calving-to-conception interval, thus affecting the calving interval and milk production, which impacts profit. However, in several studies, researchers have reported a serious decline in fertility, occurring simultaneously with increased milk yields which can be attributed to the genetic selection for higher milk yields as well as nutritional and management factors. The relationship between milk yield and characteristics of estrus has been the subject of numerous investigations (Lopez et al., Reference Lopez, Sattler and Wiltbank2004; López-Gatius et al., Reference López-Gatius, Santolaria, Mundet and Yàniz2005). Reports have demonstrated that variation in cycle length, duration and intensity of estrus has significantly increased (Kerbrat and Disenhaus, Reference Kerbrat and Disenhaus2004).

Traditionally, estrual cows were identified by visual observation. As herd size increases, visual observation of individual cows is not practical within the available time of the herd manager, resulting in unobserved estrus and remarkable economic losses. Detection efficiency is often below 50% in dairy herds (Van Vliet and Van Eerdenburg, Reference Van Vliet and van Eerdenburg1996). Although poor reproductive performance causes the highest culling rate, few cows are described to be infertile. About 90% of the factors for low detection rates can be attributed to management and 10% to the cow (Diskin and Sreenan, Reference Diskin and Sreenan2000). Due to the high variability in duration and intensity of the expressed estrous signs among individuals and the great influence of a number of various factors, detection of estrual cows is still a major problem.

(Fully) Automated sensor-based technologies that continuously monitor and record detailed information about the cow have been developed and greatly refined to attenuate further reproductive declines.

The purpose of this paper is to review relevant estrus characteristics to gain detailed knowledge of behavioral alterations at the onset of estrus as a necessary basis for developing technologies to improve the reproductive management on dairy farms. Factors affecting estrus expression and its detection are described in order to improve the balance between sensitivity and specificity of detection. The most successful methods are based on automated estrus detection. Thereby, a high priority is given to detection based on sensor-supported activity monitoring and to the potential of combination of activity measurement and several other strategies to identify cows in estrus.

Behavioral signs of estrus

Ovarian functions (follicle development, ovulation, luteinisation and luteolysis) are regulated by endocrine hormones secreted by the hypothalamus (gonadotropin-releasing hormone (GnRH)), anterior pituitary (FSH and LH), ovaries (progesterone, estradiol and inhibin) and the uterus (prostaglandin F2 α (PGF2 α )) (Aungier et al., Reference Aungier, Roche, Duffy, Scully and Crowe2015). Elevated concentrations of estradiol secreted by the pre-ovulatory follicle in turn promote a GnRH surge and allow – when progesterone levels are low – the expression of behavioral estrus and the release of LH to cause ovulation (Figure 1). Estrous behavior can be classified on the basis of primary and secondary signs.

Figure 1 Hormone patterns of cow’s estrous cycle, modified from Senger (Reference Senger2003).

Primary sign of estrus

In various studies, standing to be mounted was the primary and most characteristic external sign for determining when a cow is in estrus and considered sexually receptive for AI. But, an advancing decrease in the number of cows showing standing estrus is well documented (At-Taras and Spahr, Reference At-Taras and Spahr2001). In a number of previous studies, <50% of the cows stood to be mounted on the day of estrus (Peralta et al., Reference Peralta, Pearson and Nebel2005). The duration of estrus based on standing mounts averaged 7.6 mounts/cow with a mean duration of 4 s (Sveberg et al., Reference Sveberg, Refsdal, Erhard, Kommisrud, Aldrin, Tvete, Buckley, Waldmann and Ropstad2013) and 8 to 9 h (Walker et al., Reference Walker, Nebel and McGilliard1996) but it could be <6 h in some dairy herds (At-Taras and Spahr, Reference At-Taras and Spahr2001). Duration is significantly affected by daily milk production. To characterize the relationship between milk yield and duration of estrus, Wiltbank et al. (Reference Wiltbank, Lopez, Sartori, Sangsritavong and Gümen2006) noted a correlation coefficient of r=−0.51. This may be the result of a lower serum estradiol concentration on the day of high-yielding cows’ estrus (Lopez et al., Reference Lopez, Sattler and Wiltbank2004) due to increased metabolic clearance rate of steroid hormones (Wiltbank et al., Reference Wiltbank, Lopez, Sartori, Sangsritavong and Gümen2006). Length of time during which high-yielding cows (⩾39.5 kg/day) expressed estrous signs was 6.2 h compared with the duration of 10.9 h in cows with lower milk yields (<39.5 kg/day) (Lopez et al., Reference Lopez, Sattler and Wiltbank2004). Peralta et al. (Reference Peralta, Pearson and Nebel2005) found a significantly lower number of standing events for cows in the third lactation (5.6±2.8) compared with those in the second (6.2±3.5) and first lactations (9.2±6.6). Over the past several years, there has been a clear trend toward the use of technological methods for accurate detection of estrus in dairy cattle. Mount detector are used to record standing events, whereas pedometers and accelerometers are based on detection of increased activity during proestrus. Table 1 demonstrates the differences in the length of time cows displaying estrus behaviors depending on the detection method. Duration and these behavioral symptoms of cows’ estrus reveal a dependency on housing system and floor surfaces.

Table 1 Mean duration of cow’s estrus in dependence on the detection method and the housing type (References since 2000)

The number of standing mounts was significantly reduced under housed (52% of cows) than under pasture conditions (91% of cows) – irrespective of the detection method (Palmer et al., Reference Palmer, Olmos, Boyle and Mee2010). Because not all estrual cows expressed standing estrus (Britt et al., Reference Britt, Scott, Armstrong and Whitacre1986), Kerbrat and Disenhaus (Reference Kerbrat and Disenhaus2004) focused on secondary signs to enhance detection of estrus.

Secondary signs of estrus

Mounting behavior

Researchers published many secondary symptoms of estrus which seem more indicative than standing behavior. According to studies of Yoshida and Nakao (Reference Yoshida and Nakao2005) differences in secondary signs occurred on average 9.6 h before the onset of standing estrus and persisted until 18.4 h after the end of this primary sign. Mounting or attempting to mount other cows have a high frequency during estrus compared with other days (Kerbrat and Disenhaus, Reference Kerbrat and Disenhaus2004). A significant increase in the frequency of mounting was detectable in the period between 6 to 1 h before and 3 h after standing estrus (Sveberg et al., Reference Sveberg, Refsdal, Erhard, Kommisrud, Aldrin, Tvete, Buckley, Waldmann and Ropstad2013). Mounting behavior was observed in 80% of the cows with an average number of mounts of 2.9 (Van Vliet and Van Eerdenburg, Reference Van Vliet and van Eerdenburg1996). Front mounts were observed rather infrequently as Britt et al. (Reference Britt, Scott, Armstrong and Whitacre1986) found only 3.4% of the cows attempting to mount another cow from the front. In a recent report, the average duration of mounting estrus was 12.9 h (Sveberg et al., Reference Sveberg, Refsdal, Erhard, Kommisrud, Aldrin, Tvete, Buckley, Waldmann and Ropstad2013). The mean number of mounts – with a total standing time between 21.7 and 28.2 s – was lower for cows with milk production above than for cows with milk yields below the herd average (6.3±0.5 v. 8.6±0.5) (Lopez et al., Reference Lopez, Sattler and Wiltbank2004). Because mounting activity was lowest in heifers (5.5 mounts/h) and increased to 7.9 mounts/h for cows in the fourth lactation, Gwazdauskas et al. (Reference Gwazdauskas, Lineweaver and McGilliard1983) suggested an association with sexual experience.

It is well known that the number of mounts per cow and the length of mounting revealed a significant dependency on housing conditions. According to Britt et al. (Reference Britt, Scott, Armstrong and Whitacre1986) floor type was the most important factor affecting estrous behavior. Cows showed a clear preference for mounting – 3- to 15-fold greater – and further secondary signs (butting, sniffing, licking, chin-resting) on soft than on concrete surface. Equally, the time during which cows displayed standing and mounting behavior was longer on soft than on concrete surfaces (13.8 v. 9.4 h) (Britt et al., Reference Britt, Scott, Armstrong and Whitacre1986). Mounting activity was markedly inhibited by slippery floors, especially in cows that previously sustained a fall when attempting to mount another cow during estrus (Palmer et al., Reference Palmer, Olmos, Boyle and Mee2010). The climate in the livestock house, where temperature and relative air humidity are important factors, becomes an additional stressor. Expression of mounting activity was not inhibited as long as the maximum environmental temperature on the estrous day remained within the cows’ thermoneutral zone. Beyond 30°C, as observed by Gwazdauskas et al. (Reference Gwazdauskas, Lineweaver and McGilliard1983), temperature negatively impacted the number of mounts. There was a reduction in LH secretion leading to suppressed synthesis of follicular steroids thus, reduced plasma estradiol concentrations contributing to impaired detection of estrus (De Rensis and Scaramuzzi, Reference Dela Rue, Kamphuis, Burke and Jago2003). Use of artificial cooling methods including installation of shaded areas, fans, sprinkler systems allowed overcoming the detrimental effects of hyperthermia on fertility in dairy cattle, but the improvement of fertility did not correspond with normal winter fertility (De Rensis and Scaramuzzi, Reference Dela Rue, Kamphuis, Burke and Jago2003).

Activity

Activity increases markedly in cows approaching estrus (e.g. Valenza et al., Reference Valenza, Giordano, Lopes, Vincenti, Amundson and Fricke2012; Reith et al., Reference Reith, Brandt and Hoy2014a; Madureira et al., Reference Madureira, Silper, Burnett, Polsky, Cruppe, Veira, Vasconcelos and Cerr2015), indicating a reliable prediction of sexual restlessness. Cows were between 2.3 and 6 times (Redden et al., Reference Redden, Kennedy, Ingalls and Gilson1993; Silper et al., Reference Silper, Madureira, Kaur, Burnett and Cerri2015; Gaillard et al., Reference Gaillard, Barbu, Sørensen, Sehested, Callesen and Vestergaard2016) as active at the time of estrus – mostly defined as day 0 – as when not in estrus. Compared with the day before estrus, the time spent walking increased by 342% with a range from 21% to 913% on the estrous day for each cow, lasting from 8 h before to 5 h after the onset of estrus (Kerbrat and Disenhaus, Reference Kerbrat and Disenhaus2004). Activity – measured by an accelerometer system fitted on the neck collar of each cow – was 17±1 movements/h higher at the time of estrus compared with the 5 days before the estrous day (Gaillard et al., Reference Gaillard, Barbu, Sørensen, Sehested, Callesen and Vestergaard2016). They further found more cows showing activity at the 8th than at the 2nd observed estrus (63.3% and 45.9%, respectively). Duration of activity episodes varied between 11 and 19.1 h (Table 1). Thereby, multiparous cows expressed lower intensity (Reith et al., Reference Reith, Brandt and Hoy2014a) and peak activity (Madureira et al., Reference Madureira, Silper, Burnett, Polsky, Cruppe, Veira, Vasconcelos and Cerr2015) as previously shown by López-Gatius et al. (Reference López-Gatius, Santolaria, Mundet and Yàniz2005) who calculated that each additional lactation number caused a 21.4% decrease in locomotion. Negative effects of high milk production on activity were reported by Yániz et al. (Reference Yàniz, Santolaria, Giribet and López-Gatius2006) and López-Gatius et al. (Reference López-Gatius, Santolaria, Mundet and Yàniz2005) who observed a decrease of 1.6% in walking activity when a cow’s milk production increased by 1 kg. Referring to investigations of various researchers, activity correlates positively with most of the other behavioral symptoms including standing estrus, mounting behavior, chin-resting, sniffing, butting (Van Vliet and Van Eerdenburg, Reference Van Vliet and van Eerdenburg1996; Roelofs et al., Reference Roelofs, van Eerdenburg, Hazeleger, Soede and Kemp2005), as well as with the occurrence of another cow displaying estrous behavior. According to Yániz et al. (Reference Yàniz, Santolaria, Giribet and López-Gatius2006) expression of walking activity increased by 6.1% for each additional estrual cow. Most estrual cows were more restless between 0200 and 0800 h (Reith et al., Reference Reith, Brandt and Hoy2014a). But, in farms, cows expressing estrus at nighttime and in the morning hours could remain undetected by herd managers when only visual observation of estrus is used.

Hot climatic conditions are major factors depressing reproductive efficiency due to reduced duration and intensity of estrus and a larger range in cycle length contributing to low detection and pregnancy rates. Using pedometers for estrus detection Schüller et al. (Reference Schüller, Burfeind and Heuwieser2016) found a lower conception rate – cows were between 63% and 80% less likely to get pregnant – during long- and short-term heat stress independent of the type of semen employed compared with animals without stress. López-Gatius et al. (Reference López-Gatius, Santolaria, Mundet and Yàniz2005) detected a significantly lower increase in walking activity during the summer season (May to September) than that measured during the period from October to April (369±152% v. 384±156%). Similarly, an increase in mean relative humidity higher than 95% was associated with a decrease in walking activity at estrus (Yániz et al., Reference Yàniz, Santolaria, Giribet and López-Gatius2006). In correlation with activity, heat stress indirectly affected reproductive performance by reduced appetite and dry matter intake (DMI) which prolonged the period of negative energy balance (NEB) in early lactation (De Rensis and Scaramuzzi, Reference Dela Rue, Kamphuis, Burke and Jago2003).

Rumination time

Cows spend about one-third of the day ruminating. Using a microphone-based system for automatic recording of cow’s individual rumination time Reith et al. (Reference Reith, Brandt and Hoy2014a) observed an average daily rumination time of 442 min. The circadian rhythm of rumination time was found to be bimodal. Maximum levels were measured between 0200 and 0400 h and around noon between 1200 and 1400 h. Compared to behavior on non-estrous days cows initiating estrus showed a reduction of rumination time. Duration decreased gradually starting 2 days before the onset of estrus. The minimum level was identified on the estrous day, after which rumination time returned to base level again. On average, data of daily rumination time were reduced by 19.6% (83 min/day) with lowest values between 0400 and 1000 h on the day of estrus. These cows with less time spent ruminating at estrus were characterized by tendential higher activity. Rumination time during estrus was associated with average daily milk yield. Cows with a daily milk yield >40 kg exhibited the greatest decline compared with those with a production ⩽40 kg/day (Reith et al., Reference Reith, Brandt and Hoy2014a).

Besides rumination time, DMI and cow’s water consumption which were automatically measured by troughs placed on an electronic floor scale are reduced at estrus. With a decline of on average 14.6%, most cows (85%) consumed significantly less dry matter of the forage ration – concentrate intake was not affected by estrus – during estrus in comparison with non-estrous days (20.4 v. 23.0 kg). Similarly, estrual cows drank less water. Water intake was reduced by 15.3% in 67% of all cows, with the lowest value determined on the day before estrus relative to the reference period (Reith et al., Reference Reith, Pries, Verhülsdonk, Brandt and Hoy2014b).

Agonistic interactions

In the period of estrus, the cows are more motivated to involve in agonistic interactions than during di-estrus. Aggressive interactions were exhibited more intensively on the day of estrus than on all other days. With an incidence of 73.4% the most frequent agonistic behavior was head-to-head butting. Thereby, the number of butts was correlated positively with approach-walking (Kerbrat and Disenhaus, Reference Kerbrat and Disenhaus2004) and pedometer readings, respectively (Van Vliet and Van Eerdenburg, Reference Van Vliet and van Eerdenburg1996). Butting occurred at high incidence at the same time as mounting before standing estrus in the pre-ovulatory period (Sveberg et al., Reference Sveberg, Refsdal, Erhard, Kommisrud, Aldrin, Tvete, Buckley, Waldmann and Ropstad2011). Push-away behavior, during which the initiating cow pushes the receiving cow with its head, was the only agonistic behavior displayed relatively infrequently in estrual cattle (Sveberg et al., Reference Sveberg, Refsdal, Erhard, Kommisrud, Aldrin, Tvete, Buckley, Waldmann and Ropstad2011).

Social interactions

Chin-resting/chin-rubbing, sniffing/licking the anogenital region (vulva) of another cow and orientation are classified as social behaviors. Chin-resting and sniffing/licking represented 48.0% and 21.7%, respectively, of all sexual interactions on the day of estrus (Kerbrat and Disenhaus, Reference Kerbrat and Disenhaus2004). In order to determine important symptoms for detection of estrus, they analyzed correlations between estradiol concentration and some typical symptoms. Differences in correlation factors indicated that mounting, unrest and chin-resting are more indicative of estrus than sniffing vulva (Kerbrat and Disenhaus, Reference Kerbrat and Disenhaus2004). Increased frequencies of these signs were found especially during standing estrus (Sveberg et al., Reference Sveberg, Refsdal, Erhard, Kommisrud, Aldrin, Tvete, Buckley, Waldmann and Ropstad2011).

Generally, social as well as agonistic interactions are mainly affected by stocking density. It was found that increasing stocking density enhanced the number of cows meeting and interacting sexually as well as that overcrowding reduced the display of estrous signs because of no adequate space in housing systems (Diskin and Sreenan, Reference Diskin and Sreenan2000). Previous studies have demonstrated that the number of cows simultaneously in estrus affected both intensity of sexual activities (Britt et al., Reference Britt, Scott, Armstrong and Whitacre1986; Diskin and Sreenan, Reference Diskin and Sreenan2000) and duration of behavioral signs (Van Vliet and Van Eerdenburg, Reference Van Vliet and van Eerdenburg1996; Roelofs et al., Reference Roelofs, van Eerdenburg, Hazeleger, Soede and Kemp2005). The length varied between 11.6±4.9 and 16.1±8.2 h with one or more cows becoming estrous (Van Vliet and Van Eerdenburg, Reference Van Vliet and van Eerdenburg1996). Cows receive some sexual stimulation by the estrual group, contributing to the manifestation of estrous behaviors. Thus, cows often participate in sexually active groups during estrus, in which some cows are more attractive and sexually active than other animals in the herd (Sveberg et al., Reference Sveberg, Refsdal, Erhard, Kommisrud, Aldrin, Tvete, Buckley, Waldmann and Ropstad2013).

Management-related factors affecting estrous behavior

Nutrition

Fertility of modern dairy cows is affected by the process of postpartum metabolic adaptation regulating the resumption of estrous activity. As milk yield of dairy cows is closely related to DMI, nutritional requirements increase rapidly in the early lactation (Wiltbank et al., Reference Wiltbank, Lopez, Sartori, Sangsritavong and Gümen2006). The most important factor to explain impaired reproductive performance is the cow’s energy balance, the difference between the available energy from feed intake and the amount of energy needed for maintenance and milk production. To meet the huge demands of lactation cows usually enter a period of NEB causing – dependent on the extent and duration of NEB – inhibited expression of estrous behaviors and development of further reproductive dysfunctions. Estrus is negatively affected by alterations in blood metabolites and hormone profiles including glucose, insulin, IGF-I, non-esterified fatty acids, β-hydroxybutyrate (Wathes et al., Reference Wathes, Fenwick, Cheng, Bourne, Llewellyn, Morris, Kenny, Murphy and Fitzpatrick2007). A status of NEB decreases hypothalamic production of GnRH and, in turn, suppresses pulsatile LH secretion and circulating estrogen and progesterone concentrations (Wiltbank et al., Reference Wiltbank, Lopez, Sartori, Sangsritavong and Gümen2006; Wathes et al., Reference Wathes, Fenwick, Cheng, Bourne, Llewellyn, Morris, Kenny, Murphy and Fitzpatrick2007), explaining the decrease in duration and intensity of estrus (Lopez et al., Reference Lopez, Sattler and Wiltbank2004). Body reserves are mobilized to compensate for NEB and contribute to higher loss of BW and body condition score (BCS) (Liefers et al., Reference Liefers, Veerkamp, te Pas, Delavaud, Chilliard and van der Lende2003) which in turn affects fertility by fewer cows showing initiated estrus. In a recent study conducted by Madureira et al. (Reference Madureira, Silper, Burnett, Polsky, Cruppe, Veira, Vasconcelos and Cerr2015) the BCS of an estrual cow affected significantly peak activity, as animals with BCS ⩽2.5 expressed less intense estrus patterns. In addition, NEB has been related to delayed resumption of ovarian activity, prolonged postpartum anestrus (Liefers et al., Reference Liefers, Veerkamp, te Pas, Delavaud, Chilliard and van der Lende2003), a greater incidence of irregular cycles (Wathes et al., Reference Wathes, Fenwick, Cheng, Bourne, Llewellyn, Morris, Kenny, Murphy and Fitzpatrick2007), decreased conception rates and increased pregnancy loss (Wiltbank et al., Reference Wiltbank, Lopez, Sartori, Sangsritavong and Gümen2006). In contrast, cows in a positive energy balance were found to have 11.3 days less until first postpartum luteal activity reducing calving-to-conception interval (Liefers et al., Reference Liefers, Veerkamp, te Pas, Delavaud, Chilliard and van der Lende2003).

Nevertheless, López-Gatius et al. (Reference López-Gatius, Santolaria, Mundet and Yàniz2005) expected no effect of NEB on the intensity of estrus expression and there have been, indeed, some high-yielding cows being able to maintain high fertility in spite of the described influence of milk production on reproductive function.

Hormonal therapy

Synchronization of estrus by reproductive hormones has been used to stimulate herd fertility and to increase the efficiency of estrus detection rates in dairy herds (De Rensis and Scaramuzzi, Reference Dela Rue, Kamphuis, Burke and Jago2003). But, duration and intensity of estrus were highly variable and were not different between estrous cycles induced by PGF2 α and those occurring spontaneously (Walker et al., Reference Walker, Nebel and McGilliard1996). Using a progesterone-releasing intravaginal device (PRID) for estrus synchronization López-Gatius et al. (Reference López-Gatius, Santolaria, Mundet and Yàniz2005) compared the effect of natural and PRID induced estrus on activity behavior and found cows treated with the PRID expressing similar walking activity to cows in natural estrus.

The use of synchronization of ovulation that allows for fixed timed AI eliminates the need for detection of estrus (Dolecheck et al., Reference Dolecheck, Silvia, Heersche, Wood, McQuerry and Bewley2016). The goal is as early as possible to simultaneously and blindly inseminate all injected cows. The administration of GnRH results in ovulation and formation of a new or accessory corpus luteum (CL) and coincides with initiation of a new follicular wave. The CL regresses after the injection of PGF2 α which follows 7 days later. Cows receive a second injection of GnRH 48 h after the luteolytic treatment to induce a fertile ovulation followed by timed AI 24 h later. Dolecheck et al. (Reference Dolecheck, Silvia, Heersche, Wood, McQuerry and Bewley2016) found no difference in probability of pregnancy or pregnancy loss between cows with estrus detected by increased pedometer activity and cows which were subjected to an ovulation synchronization program. Fricke et al. (Reference Fricke, Giordano, Valenza, Lopes, Amundson and Carvalho2014) who also compared the effectiveness of timed AI with or without detection by an automated activity measurement showed that supplementing timed AI with activity monitoring resulted in reduced time to first service by 7.5 to 12.4 days.

In the United States pre-synchronization is widely used in dairy farms, whereupon in a study conducted by Fricke et al. (Reference Fricke, Giordano, Valenza, Lopes, Amundson and Carvalho2014) the accelerometer attached to the neck collar detected 70% of the cows. Pregnancy rate of cows with enhanced activity after completing the second PGF2 α injection of a Presynch-Ovsynch protocol and following AI was 27% whereas pregnancy rate was increased to 40% in cows with enhanced activity and additional timed AI after pre-synchronization. According to Valenza et al. (Reference Valenza, Giordano, Lopes, Vincenti, Amundson and Fricke2012) using activity monitoring systems and heatmount detectors for identifying cows in estrus, increased activity and standing behavior was detected in only 71% and 66% of synchronized cows. Multiple reproductive management programs can be economically feasible in dairy farms. However, for success timed AI demands strict observance and labor (Dolecheck et al., Reference Dolecheck, Silvia, Heersche, Wood, McQuerry and Bewley2016).

Fully automated systems for detection of cow’s estrus

Pressure sensing system

Electronic pressure-sensitive devices such as HeatWatch® (DDx Inc., Boulder, CO, USA) (Walker et al., Reference Walker, Nebel and McGilliard1996; At-Taras and Spahr, Reference At-Taras and Spahr2001) or DEC® (IMV Technologies, L’Aigle, France) (Saumande, Reference Saumande2002) are based on detection of onset and length of standing mounts accepted by estrual cows. The system consists of a pressure-sensitive transmitter which is embedded in a burlap pouch and glued to the sacral region anterior to the tail head (Walker et al., Reference Walker, Nebel and McGilliard1996; Saint-Dizier and Chastant-Maillard, Reference Saint-Dizier and Chastant-Maillard2012). This on-cow sensor is activated by the weight of a mounting animal for a minimum of 2 s to limit the number of false-positive results, although it has been found that up to 40% of mounts lasted <2 s (Walker et al., Reference Walker, Nebel and McGilliard1996). Via radio signal data (date, time, cow ID, number and duration of mounts, signal strength) are sent within a 1200-m radius to a receiver and recorded by the management software on a farm computer (At-Taras and Spahr, Reference At-Taras and Spahr2001; Saint-Dizier and Chastant-Maillard, Reference Saint-Dizier and Chastant-Maillard2012). A defined algorithm analyzes each cow’s mounting profile with the software classifying a ‘standing’ as three or more standing events in any 4-h period (Diskin and Sreenan, Reference Diskin and Sreenan2000; Peralta et al., Reference Peralta, Pearson and Nebel2005). Initiation of estrus is confirmed by the first activation of the sensor (Lopez et al., Reference Lopez, Sattler and Wiltbank2004). The software provides various reports including lists and graphs of cows defined as standing or suspected of standing – depending on whether cows receiving or not receiving three or more mounts within the 4-h period (At-Taras and Spahr, Reference At-Taras and Spahr2001). Use of that system resulted in detection of 82.1% of the ovulations (Lopez et al., Reference Lopez, Sattler and Wiltbank2004) and improved detection of estrus compared with visual observation. In two different trials, At-Taras and Spahr (Reference At-Taras and Spahr2001) found efficiencies of 86.8% and 71.1% for detection based on HeatWatch® in comparison with 54.4% and 54.7% provided by visual observation of cows. However, similar efficiencies – 48.0% identified by the system v. 49.3% by visual observation – were indicated in a study conducted by Peralta et al. (Reference Peralta, Pearson and Nebel2005). The efficiency of the DEC® system was reported to be considerably lower, that is to say approximately only 50% of the efficiency obtained from visual observation (35.4% v. 68.8%) (Saumande, Reference Saumande2002). The potential of pressure-sensitive systems was affected significantly by housing conditions (Palmer et al., Reference Palmer, Olmos, Boyle and Mee2010), type of flooring (Britt et al., Reference Britt, Scott, Armstrong and Whitacre1986), weather (Peralta et al., Reference Peralta, Pearson and Nebel2005) and difficulties in maintaining the sensors in the proper position (Diskin and Sreenan, Reference Diskin and Sreenan2000). Displacements or losses of sensors up to 40% were described by Saumande (Reference Saumande2002).

Activity monitoring

Pedometer

Pedometers attached to the leg of the cow record the number of steps taken per unit time as an indicator of walking activity being markedly increased during proestrus and estrus of dairy cows (López-Gatius et al., Reference López-Gatius, Santolaria, Mundet and Yàniz2005; Roelofs et al., Reference Roelofs, van Eerdenburg, Hazeleger, Soede and Kemp2005; Yániz et al., Reference Yàniz, Santolaria, Giribet and López-Gatius2006). Various researches evaluated these commercially available systems as a reliable method of identifying estrual animals as well as useful for prediction of ovulation time (Roelofs et al., Reference Roelofs, van Eerdenburg, Hazeleger, Soede and Kemp2005). Further, López-Gatius et al. (Reference López-Gatius, Santolaria, Mundet and Yàniz2005) found a positive relationship between walking activity and pregnancy rate of dairy cows.

More precisely, cows coming into estrus are identified by an increase in locomotion above the mean activity value recorded – during the same time period – for preceding days (Roelofs et al., Reference Roelofs, van Eerdenburg, Hazeleger, Soede and Kemp2005; Yániz et al., Reference Yàniz, Santolaria, Giribet and López-Gatius2006). The system described by Dolecheck et al. (Reference Dolecheck, Silvia, Heersche, Wood, McQuerry and Bewley2016) calculated a 10-day backward moving mean steps per hour after each data download. Pedometer recordings showed a diurnal rhythm in the number of steps which is important for the development of algorithms considering within-cow comparisons. Alerts are generated using different algorithms and are set off if weighted activity has exceeded a user-defined threshold value (Roelofs et al., Reference Roelofs, van Eerdenburg, Hazeleger, Soede and Kemp2005, Dolecheck et al., Reference Dolecheck, Silvia, Heersche, Wood, McQuerry and Bewley2016). The detection rates and error rates for the different thresholds used to study the increase in the number of steps around estrus have been reported (Redden et al., Reference Redden, Kennedy, Ingalls and Gilson1993; Roelofs et al., Reference Roelofs, van Eerdenburg, Hazeleger, Soede and Kemp2005). Data stored in a memory are transferred to receivers usually placed near the milking system and sent to the management software (Roelofs et al., Reference Roelofs, van Eerdenburg, Hazeleger, Soede and Kemp2005) enabling herd managers to review the reproductive status of individual cows.

Accelerometer system

Activity meters using acceleration technology are attached to the neck collar of each cow (Madureira et al., Reference Madureira, Silper, Burnett, Polsky, Cruppe, Veira, Vasconcelos and Cerr2015; Gaillard et al., Reference Gaillard, Barbu, Sørensen, Sehested, Callesen and Vestergaard2016) and measure continuously horizontal accelerations related to upward movements of cow’s head and neck during walking and mounting behavior (Reith et al., Reference Reith, Brandt and Hoy2014a). Data present average activity shown as a general activity index (Silper et al., Reference Silper, Madureira, Kaur, Burnett and Cerri2015) which can be stored in 1-h (Gaillard et al., Reference Gaillard, Barbu, Sørensen, Sehested, Callesen and Vestergaard2016) or 2-h intervals each day (Reith et al., Reference Reith, Brandt and Hoy2014a; Madureira et al., Reference Madureira, Silper, Burnett, Polsky, Cruppe, Veira, Vasconcelos and Cerr2015). Specially developed algorithms based on deviations of the current measured data from the stored activity pattern are used to separate cow’s day-to-day activity from activities associated with estrous behavior. Herdsmen receive an alert after cows have exceeded a user-defined threshold. Data are read by an antenna and automatically transferred via IR signal to the herd management software providing lists and graphs to control reproductive (and health) status of individual cows (Reith et al., Reference Reith, Brandt and Hoy2014a) (Figure 2).

Figure 2 Acceleration technology attached to cow’s neck collar.

Aungier et al. (Reference Aungier, Roche, Duffy, Scully and Crowe2015) showed that the start of estrus-related behavior was 6 h before the start of an activity cluster recorded by Heatime® (SCR Engineers Ltd, Netanya, Israel) and finished 3 h after the start of the activity cluster. In their investigation the system alerted estrus in 90% of cows and incorrectly identified 17% of the total number of clusters. Further, Valenza et al. (Reference Valenza, Giordano, Lopes, Vincenti, Amundson and Fricke2012) verified that the percentage of cows detected in estrus did not differ between the accelerometer system and the heatmount detectors (71% v. 66%, respectively). Thus, accelerometer systems are described as a useful tool to detect estrus and to improve fertility in dairy cattle (Valenza et al., Reference Valenza, Giordano, Lopes, Vincenti, Amundson and Fricke2012). The technology is commercially available for measurement of activity only or in combination with rumination characteristics (Reith et al., Reference Reith, Brandt and Hoy2014a).

Video camera

The use of video systems for estrus detection relies upon identification of the standing mount position. So, the length of time during which cows exhibit standing estrus is comparable with the average duration measured by pressure sensing systems. Cameras fixed preferably in the upper corners at a height of 3 m are connected to the video management software providing visualization of stored video sequences. Detection is affected by camera resolution, as low resolution may result in difficulties in reading of the ear-tag number and, thus, identifying the cow (Saint-Dizier and Chastant-Maillard, Reference Saint-Dizier and Chastant-Maillard2012), disposition and the used threshold value. Although these systems are equipped with IR technology, artificial lighting is necessary at nighttime (Bruyère et al., Reference Bruyère, Hétreau, Ponsart, Gatien, Buff, Disenhaus, Giroud and Guérin2012). Compared with a duration of 40 min/day (four periods of 10 min) needed for visual observation, the time exposure to analyze the video sequences varied between 8 and 32 min, depending on the number of cows that were simultaneously in estrus (Bruyère et al., Reference Bruyère, Hétreau, Ponsart, Gatien, Buff, Disenhaus, Giroud and Guérin2012). Due to investigations conducted by Bruyère et al. (Reference Bruyère, Hétreau, Ponsart, Gatien, Buff, Disenhaus, Giroud and Guérin2012) the efficiency for detection based on video recording was higher in comparison with the detection rate obtained from classical visual observation (80% v. 68.6%). They concluded that using video cameras for detection of estrus can replace visual observation. Nevertheless, as with visual observation, only cows with obvious behavioral estrous signs are detected.

Recording of vocalization

The vocal behavior of cattle gives information on the reproductive status of the vocalizing animal and may bear upon estrus advertisement. Near the time of estrus vocalization rate was found to be increased (Schön et al., Reference Schön, Hämel, Puppe, Tuchscherer, Kanitz and Manteuffel2007), with the extent of vocalizations depending on the status of the estrous cycle: di-estrus<pro- and postestrus<estrus (Dreschel, Reference Dreschel2014). Vocalizations are recorded continuously by a clip-on microphone attached to a neck harness of the animal. Via a transmitter the recordings are transferred to a stationary receiver being connected to the sound card of the computer. By use of the available algorithm, serial signal windows are generated from the sound recording and only those with means exceeding a defined threshold are considered for detection of estrus. However, large individual variability of absolute vocalization rate might reduce the suitability of this trait for practical application (Schön et al., Reference Schön, Hämel, Puppe, Tuchscherer, Kanitz and Manteuffel2007).

Measurement of body temperature

Automated systems of monitoring body temperature around estrus are based on radiotelemetric transmission of information. The temperature rhythms have been recorded by rectal (Piccione et al., Reference Piccione, Caola and Refinetti2003) and vaginal thermometry (Fisher et al., Reference Fisher, Morton, Dempsey, Henshall and Hill2008). According to Fisher et al. (Reference Fisher, Morton, Dempsey, Henshall and Hill2008), the vaginal temperature decreased slightly 2 days before the day of estrus followed by an increase at the time of the LH peak. In their study, the average temperature increase was 0.48°C ranging from 0.40°C to 3.22°C in estrous Holstein Friesian cows. In a study conducted by Redden et al. (Reference Redden, Kennedy, Ingalls and Gilson1993), transmitters enclosed by a support anchor with finger-like projections were inserted into the vagina to a depth of 20 cm. Transmitter signals were picked up by specific receivers which were connected to a computer. Others used microprocessor-controlled temperature loggers (size=92×20 mm; weight=40.5 g) placed in the vaginal cavity (Suthar et al., Reference Suthar, Burfeind, Patel, Dhami and Heuwieser2011) or on-chip temperature sensors implanted in the cow’s vulvar muscle – connected with receivers located in the collar (Morais et al., Reference Morais, Valente, Almeida, Silva, Soares, MJCS, Valentim and Azevedo2006). Piccione et al. (Reference Piccione, Caola and Refinetti2003) used a rectal probe inserted 15 cm into cow’s rectum. With small seasonal variations, increases in body temperature occurred every 21 days on the day of estrus. Nevertheless, the records of the body temperature of four representative cows resulted in a detection rate of only 78% and a false positive rate of 12%. As the interval between the onset of increasing temperature and the time of ovulation was found to be consistent, the use of this predictor may be a reliable indicator of ovulation and the time of the LH surge (Fisher et al., Reference Fisher, Morton, Dempsey, Henshall and Hill2008). However, limitations may be due to variation in environmental temperature, disease-related hyperthermia, or some systemic or local inflammation, increasing the incidence of false positive results (Fisher et al., Reference Fisher, Morton, Dempsey, Henshall and Hill2008).

Measurement of milk progesterone concentration

As the blood concentration of progesterone is closely associated with its concentration in milk, progesterone analysis of representative milk samples can be used to determine the reproductive status of the dairy cow. The development of in-line and real-time automatic monitoring systems such as Herd Navigator® (DeLaval, Glinde, Germany) replace the manual collecting of progesterone information. The samples taken during the milking session are collected in a sample intake unit and transferred automatically to the analyzing unit connected to a computer. The frequency of progesterone assays can be varied according to the stage of the estrous cycle (Saint-Dizier and Chastant-Maillard, Reference Saint-Dizier and Chastant-Maillard2012). Before being processed in a biological model developed by Friggens and Chagunda (Reference Friggens and Chagunda2005) the milk progesterone values prepared over the last few days are smoothed using an extended Kalman filter, with the algorithm distinguishing between different categories of cows: postpartum anestrus, estrus cycling and potentially pregnant. Alerts are generated by the software in case of milk progesterone concentrations <4 ng/ml (Friggens and Chagunda, Reference Friggens and Chagunda2005). Roelofs et al. (Reference Roelofs, Van Eerdenburg, Soede and Kemp2006) found large inter-individual variation in timing of decreased levels and noted values <5 ng/ml 80 h (range: 54 to 98 h) before ovulation. Except comparatively major investment costs, in-line measurements of milk progesterone may have the potential to be a reliable tool in reproduction monitoring (Friggens and Chagunda, Reference Friggens and Chagunda2005; Saint-Dizier and Chastant-Maillard, Reference Saint-Dizier and Chastant-Maillard2012). The fully automated system of progesterone assay in milk (Herd Navigator®), presented by Saint-Dizier and Chastant-Maillard (Reference Saint-Dizier and Chastant-Maillard2012), has been marketed in Denmark and is commercially available since 2010 with an average detection rate of 95%.

Potential of multivariate analysis including activity monitoring

Detection of cow’s estrus is a balance of sensitivity and specificity. Correctly identified estrus events are classified as true positive. Non-alerted estrus events lead to false negative results. Alerts outside estrus events are considered true negative, and alerted non-estrus events are denoted as false positive. So, the sensitivity of a specific technology expresses the percentage of correctly detected estrus events, whereas the specificity is the probability of a missing alert when an event does not occur. The percentage of false estrus alerts in relation to the number of detected estrus events is indicated by the error rate (Firk et al., Reference Firk, Stamer, Junge and Krieter2002) (Table 2). Often, there is a contradiction between the sensitivity and the specificity, as an increase in the sensitivity provokes a decline in the second parameter.

Table 2 Criteria for evaluation of methods for detection of estrus in dairy cows

TP=true positive; FN=false negative; FP=false positive; TN=true negative.

To date, most technologies for identifying cows in estrus are based on automated activity measurement (Madureira et al., Reference Madureira, Silper, Burnett, Polsky, Cruppe, Veira, Vasconcelos and Cerr2015; Dolecheck et al., Reference Dolecheck, Silvia, Heersche, Wood, McQuerry and Bewley2016). This system is repeatedly considered as being suitable for estrus detection, and is likely to be gainful for most dairy farms (Rutten et al., Reference Rutten, Steeneveld, Inchaisri and Hogeveen2014). Analyzing the economic benefits of activity meters for detecting cows in estrus they showed that the increase in sensitivity of activity meters (80%) in comparison with the detection rate caused by visual observation (50%) was the most important determinant of the profitability of the investment in such a system. Furthermore, they calculated that investing in activity measurement is less expensive than increasing the detection rate of visual estrus detection by increasing labor input.

A combination of several estrus detection aids might lead to the best results concerning sensitivity of detection. Firk et al. (Reference Firk, Stamer, Junge and Krieter2002) postulated that the aim should be to achieve an efficiency higher than 90% and an error rate lower than 20% by combination of traits. Table 3 demonstrates the advantages of univariate and multivariate analysis of continuous and close activity monitoring, especially by neck-mounted accelerometer systems for estrus detection. According to Peralta et al. (Reference Peralta, Pearson and Nebel2005), the analysis of activity measurement, visual observation and mounting detection alone resulted in low detection rates (37.2%, 49.3% and 48.0%, respectively). The subsequent combination of all three traits revealed an estrus-detection sensitivity of 80.0%. Not all combinations have practical significance due to the above-mentioned limitations. For use in the field it is important to utilize cost-effective methods with minimal labor requirements and a high degree of accuracy at identifying physiological or behavioral estrus signs. Variation in detection performance depends on the methods of calculation and definitions of algorithms as well as on differences in farm structure (housing system, health status, herd management). Setting a threshold for alerts requires a balance between false positives and false negatives. Estrual cows with modest increase in activity behavior, especially lame cows, remain undetected when the threshold is set too high to create alerts (Dolecheck et al., Reference Dolecheck, Silvia, Heersche, Wood, McQuerry and Bewley2016).

Table 3 Evaluation of activity measurement as well as combinations of methods including activity measurement for detection of estrus in dairy cows

ACT=activity; VO=visual observation.

For practical application the automated combination of activity with data that are anyway available in most dairy farms (e.g. time since last estrus, information about previous estrus events) may be ideal (Krieter, Reference Krieter2005). In addition, data about cow’s health status – rumination time is mainly used in dairy farms to predict impending metabolic disorders – can be useful for multivariate estrus detection. In their study carried out on five practical farms, Reith et al. (Reference Reith, Brandt and Hoy2014a) analyzed data of activity and rumination time which can be recorded exactly and automatically on a daily basis for individual cows by a microphone-based sensor system. They showed that simultaneous analysis improved the detection rate of cows starting estrus. Unexpectedly, the number of cows with enhanced activity at estrus was lower than that identified by rumination time (76.5% v. 86.2%), suggesting that measurement of rumination duration may detect more cows approaching estrus compared with measurement of activity. So, combined analysis greatly underscores the relevance of considering more than only one trait for identification of cows that would otherwise not be inseminated.

Conclusion

It is undisputed that detection of bovine estrus significantly affects reproductive efficiency and profitability of dairy herds. The development of improved methods of identifying estrual animals depends on the knowledge of behavioral alterations at the onset of estrus. Behavioral signs differ among individual cows in duration and intensity of estrus. Cow-related factors as well as environmental- and management-related factors influence the expression of estrus and are responsible for high inter-individual variations. Over the past several years, there has been a clear trend toward the analysis of routinely collected sensor-based data and constant surveillance of behavior. The focus is on secondary symptoms of estrus which are more indicative than standing behavior. A number of diverse automated detection systems have been refined and marketed to enhance detection of estrus. Relatively new measurements such as rumination time or feed intake are studied to further improve reproductive management in dairy farms. Prospective, biosensors for in-line measurement of bovine progesterone and combinations of several technologies including activity monitoring may promise the greatest success.

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Figure 0

Figure 1 Hormone patterns of cow’s estrous cycle, modified from Senger (2003).

Figure 1

Table 1 Mean duration of cow’s estrus in dependence on the detection method and the housing type (References since 2000)

Figure 2

Figure 2 Acceleration technology attached to cow’s neck collar.

Figure 3

Table 2 Criteria for evaluation of methods for detection of estrus in dairy cows

Figure 4

Table 3 Evaluation of activity measurement as well as combinations of methods including activity measurement for detection of estrus in dairy cows