Thermal comfort and productive responses of 7/8 holstein-gyr cows subjected to cooling system

Silva, Marcos Vinícius da; Almeida, Gledson Luiz Pontes de; Pandorfi, Héliton; Moraes, Alex Souza; Macêdo, Gleidiana Amélia Pontes de Almeida; Oliveira, Maria Eduarda Gonçalves de; Melo, Maria Vitória Neves de; Santana, Taize Calvacante

doi:10.4025/actascianimsci.v45i1.61295

ABSTRACT.

The objective of this research was to identify the influence of the evaporative adiabatic cooling system (EACS) on the thermal comfort and productive responses of dairy cattle, through multivariate analysis by principal components (PC), in the summer and winter seasons of the semiarid region of Pernambuco, Brazil. The data came from an experiment that included 16 multiparous lactating cows (7/8 Holstein-Gyr), randomly distributed in 4 sets, with 4 experimental phases and 4 treatments (0, 10, 20, and 30 min.). The multivariate analysis was carried out through PC for the thermal comfort indices, physiological variables, and milk production and composition. The highest milk production in the summer season was obtained for animals exposed to the cooling system for 30 min. In the winter season in the morning period, the use of the EACS for 10 min. was sufficient for improvements in milk production. The times of exposure to EACS caused changes in the composition of milk, for both seasons. Principal component analysis made it possible to verify a positive correlation of evaporative cooling with thermal comfort, physiological responses, and production and composition of milk of lactating cows.

Keywords:
multivariate analysis; dairy cattle; evaporative cooling system

Introduction

Tropical and subtropical regions generally have high air temperatures that affect the homeothermy of dairy cows, with negative consequences for food intake, milk production and milk composition (Garner et al., 2017Garner, J. B., Douglas, M., Williams, S. R. O., Wales, W. J., Marett, L. C., DiGiacomo, K., … Hayes, B. J. (2017). Responses of dairy cows to short-term heat stress in controlled-climate chambers. Animal Production Science, 57(7), 1233-1241. DOI: https://doi.org/10.1071/AN16472
https://doi.org/https://doi.org/10.1071/... ; Tresoldi, Schütz, & Tucker, 2019Tresoldi, G., Schütz, K. E., & Tucker, C. B. (2019). Cooling cows with sprinklers: Effects of soaker flow rate and timing on behavioral and physiological responses to heat load and production. Journal of Dairy Science , 102, 528-538. DOI: https://doi.org/10.3168/jds.2018-14962
https://doi.org/https://doi.org/10.3168/... ; Souto et al., 2021Souto, P. L. G., Barbosa, E. A., Martins, E., Martins, V. M. V., Hatamoto-Zervoudakis, L. K., Pimentel, C. M. M., & Ramos, A. F. (2021). Influence of season and external morphology on thermal comfort and physiological responses in bulls from two breeds adapted to a subtropical climate. Revista Brasileira de Saúde e Produção Animal, 22. DOI: https://doi.org/10.1590/S1519-99402122022021
https://doi.org/https://doi.org/10.1590/... ).

High milk production cows succumb to heat stress before low production animals, due to higher nutritional requirements and metabolic heat production, which significantly alter the energy balance between the animal and the environment (Shu, Wang, Guo, & Bindelle, 2021Shu, H., Wang, W., Guo, L., & Bindelle, J. (2021). Recent advances on early detection of heat strain in dairy cows using animal-based indicators: a review. Animals, 11(4), 980. DOI: https://doi.org/10.3390/ani11040980
https://doi.org/https://doi.org/10.3390/... ; Burhans, Burhans, & Baumgard, 2022Burhans, W. S., Burhans, C. R., & Baumgard, L. H. (2022). Invited review: Lethal heat stress: The putative pathophysiology of a deadly disorder in dairy cattle. Journal of Dairy Science , 105(5), 3716-3735. DOI: https://doi.org/10.3168/jds.2021-21080
https://doi.org/https://doi.org/10.3168/... ). Strategies that minimize this problem include managing the animal in the shade, using an evaporative adiabatic cooling system (EACS) and an automated cooling system (Silva & Passini, 2018Silva, D. C., & Passini, R. (2018). Assessing different holding pen cooling systems through environmental variables and productivity of lactating cows. Acta Scientiarum. Animal Sciences, 40, e36087. DOI: https://doi.org/10.4025/actascianimsci.v40i1.36087
https://doi.org/https://doi.org/10.4025/... ; Tresoldi, Schütz, & Tucker, 2019Tresoldi, G., Schütz, K. E., & Tucker, C. B. (2019). Cooling cows with sprinklers: Effects of soaker flow rate and timing on behavioral and physiological responses to heat load and production. Journal of Dairy Science , 102, 528-538. DOI: https://doi.org/10.3168/jds.2018-14962
https://doi.org/https://doi.org/10.3168/... ).

The characterization of the thermal environment using comfort indices allows the integrated assessment of more than one meteorological variable associated with the effect of stress and/or comfort on farm animals, such as the temperature and humidity index (THI) commonly used for determining the thermal condition in the housing of dairy cattle. As for phenotypic plasticity, rectal temperature is one of the main physiological variables used to identify thermal stress in dairy cattle; under normal conditions they have a body core temperature of 38.5°C and the thresholds for environmental fever vary between 39.1 and 39.7°C (Sousa, Silva Rodrigues, Abreu, Tabile, & Martello, 2018Sousa, R. V., Silva Rodrigues, A. V., Abreu, M. G., Tabile, R. A., & Martello, L. S. (2018). Predictive model based on artificial neural network for assessing beef cattle thermal stress using weather and physiological variables. Computers and Electronics in Agriculture, 144, 37-43. DOI: https://doi.org/10.1016/j.compag.2017.11.033
https://doi.org/https://doi.org/10.1016/... ; Oliveira et al., 2019Oliveira, C. C. D., Alves, F. V., Martins, P. G. M. D. A., Karvatte Junior, N. , Alves, G. F., Almeida, R. G. D., ... Costa e Silva , E. V. D. (2019). Vaginal temperature as indicative of thermoregulatory response in Nellore heifers under different microclimatic conditions. PloS one, 14(10), e0223190. DOI: https://doi.org/10.1371/journal.pone.0223190
https://doi.org/https://doi.org/10.1371/... ; Yan, Zhao, & Shi, 2020Yan, G., Li, H., Zhao, W., & Shi, Z. (2020). Evaluation of thermal indices based on their relationships with some physiological responses of housed lactating cows under heat stress. International Journal of Biometeorology, 64(12), 2077-2091. DOI: https://doi.org/10.1007/s00484-020-01999-6
https://doi.org/https://doi.org/10.1007/... ).

From the large amount of data generated to characterize the cause and effect of environmental thermal stress, one of the statistical methods to evaluate the phenomena that influence milk production is multivariate statistics, which makes it possible to explain a set of two or more variables in time (Silva et al., 2020Silva, M. V., Pandorfi, H., Almeida, G. L. P., Jardim, A. M. R. F., Batista, P. H. D., Silva, R. A. B., ... Moraes, A. S. (2020). Spatial variability and exploratory inference of abiotic factors in barn compost confinement for cattle in the semiarid. Journal of Thermal Biology, 94, 102782. DOI: https://doi.org/10.1016/j.jtherbio.2020.102782
https://doi.org/https://doi.org/10.1016/... ; Batista et al., 2021Batista, P. H. D., Almeida, G. L. P., Pandorfi, H., Silva, M. V., Silva, R. A. B., Silva, J. L. B., ... Moraes Rodrigues, J. A. (2021). Thermal images to predict the thermal comfort index for Girolando heifers in the Brazilian semiarid region. Livestock Science, 251, 104667. DOI: https://doi.org/10.1016/j.livsci.2021.104667
https://doi.org/https://doi.org/10.1016/... ; Silva et al., 2021aSilva, M. V., Almeida, G. L. P., Pandorfi, H., Moraes, A. S., Macêdo, G. A. P. A., Batista, P. H. D., ... Guiselini, C. (2021a). Influence of meteorological elements on behavioral responses of gir cows and effects on milk quality. Acta Scientiarum. Animal Sciences , 43, e52604. DOI: https://doi.org/10.4025/actascianimsci.v43i1.52604
https://doi.org/https://doi.org/10.4025/... ; bSilva, M. V., Pandorfi, H., Jardim, A. M. R. F., Oliveira-Júnior, J. F., Divincula, J. S., Giongo, P. R., ... Lopes, P. M. O. (2021b). Spatial modeling of rainfall patterns and groundwater on the coast of northeastern Brazil. Urban Climate, 38, 100911. DOI: https://doi.org/10.1016/j.uclim.2021.100911
https://doi.org/https://doi.org/10.1016/... ; Silva et al., 2022Silva, M. V., Cordeiro Junior, J. J. F., Almeida Neto, L. A., Santos, R. B., Pandorfi, H., & Guiselini, C. (2022). Micrometeorological Modification Promoted by Photoselective Meshes and Supplementary Lighting in the Production of Pre-sprouted Sugarcane Seedlings. Sugar Tech, 24, 1894-1912. DOI: https://doi.org/10.1007/s12355-021-01078-z
https://doi.org/https://doi.org/10.1007/... ). Recent research shows satisfactory results with the use of multivariate analysis, such as evaluation of influence of nutrients and experimental period on the composition and quality of bovine milk (Gabbi et al., 2018Gabbi, A. M., Mcmanus, C. M., Marques, L. T., Abreu, A. S., Machado, S. C., Zanela, M. B., ... Fischer, V. (2018). Different levels of supplied energy for lactating cows affect physicochemical attributes of milk. Journal of Animal and Feed Sciences, 27, 11-17. DOI: https://doi.org/10.22358/jafs/83703/2018
https://doi.org/https://doi.org/10.22358... ).

Given the above, this research was conducted to identify the influence of the EACS on the thermal comfort and productive responses of dairy cattle, through multivariate analysis by principal components, in the summer and winter seasons of the semiarid region of Pernambuco, Brazil.

Material and methods

The research was conducted in one database from an experiment carried out in a dairy unit (Figure 1), located in the Agreste Mesoregion, Ipojuca Valley Microregion, Pernambuco State dairy basin (8°36'34.82"S and 36°37'33.09"W; 755 m), in the summer (from February to March) and winter (from July to August), of the year 2019.

Figure 1
Location of the property in the municipality of Capoeiras, State of Pernambuco, Brazil (IBGE, 2021Instituto Brasileiro de Geografia e Estatística [IBGE]. (2021). Malha Municipal. Retrieved from https://www.ibge.gov.br/geociencias/organizacao-do-territorio/malhas-territoriais/15774-malhas.html?edicao=33087&t=acesso-ao-produto
https://www.ibge.gov.br/geociencias/orga... ).

The average rainfall in the region is 620.3 mm (Agência Pernambucana de Águas e Climas [APAC], 2019Agência Pernambucana de Águas e Climas [APAC]. (2019). Monitoramento pluviométrico. Retrieved from http://www.apac.pe.gov.br/meteorologia/monitoramento-pluvio.php
http://www.apac.pe.gov.br/meteorologia/m... ), with an average annual temperature of 20.3ºC (Instituto Nacional de Meteorologia [INMET], 2019Instituto Nacional de Meteorologia [INMET]. (2019). Banco de Dados Meteorológicos para Ensino e Pesquisa [BDMEP]. (online). Retrieved from http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep
http://www.inmet.gov.br/portal/index.php... ). According to Köppen’s classification, the region is characterized by the climate transition between “BSh” and “Aw” (Alvares, Stape, Sentelhas, Moraes Gonçalves, & Sparovek, 2013Alvares, C. A., Stape, J. L., Sentelhas, P. C., Moraes Gonçalves, J. L., & Sparovek, G. (2013). Köppen's climate classification map for Brazil. Meteorologische Zeitschrift, 22(6), 711-728. DOI: https://doi.org/10.1127/0941-2948/2013/0507
https://doi.org/https://doi.org/10.1127/... ; Beck et al., 2018Beck, H. E., Zimmermann, N. E., McVicar, T. R., Vergopolan, N., Berg, A., & Wood, E. F. (2018). Present and future Köppen-Geiger climate classification maps at 1-km resolution. Scientific Data, 5, 1-12. DOI: https://doi.org/10.1038/sdata.2018.214
https://doi.org/https://doi.org/10.1038/... ). In the summer of 2009, the average temperature based on a historical series of 30 years was 22.8ºC and in the winter it was 20.3ºC (INMET, 2019Instituto Nacional de Meteorologia [INMET]. (2019). Banco de Dados Meteorológicos para Ensino e Pesquisa [BDMEP]. (online). Retrieved from http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep
http://www.inmet.gov.br/portal/index.php... ).

The experiment was conducted using 16 lactating multiparous Girolando cows (7/8 Holstein-Gyr), with an average weight of 500 kg and average milk production of 18 kg day^-1, randomly distributed in 4 sets (S1, S2, S3, and S4), with 4 experimental phases (P1, P2, P3, and P4) and 4 times of exposure of the animals to the evaporative adiabatic cooling - EACS (0, 10, 20 and 30 min.).

The experimental period was 56 days for the summer and 56 days for the winter, totaling 112 days for the entire experiment. Each season was divided into 4 phases of 14 days, with the first seven days of each phase intended for the animals to adapt to the pre-milking acclimation times of 10, 20 and 30 min. under EACS, plus the control (0 min.). The other seven subsequent days were used to record the meteorological variables in the waiting pen, physiological responses, and production of lactating cows, with subsequent determination of the composition of the milk.

To determine the comfort indices, the meteorological variables air temperature (T, ºC), relative air humidity (RH, %) and the temperature of the black globe (BGT, ºC) were recorded through dataloggers HOBO Pro Dataloggers HB8 model, with a temperature measurement range between -20 and 70 (± 0.35°C) and relative humidity between 5 and 100 (± 2.5%). The wind speed (m s^-1) was recorded by a propeller anemometer. The sensors were positioned in the geometric center of the waiting room, at 2.5 m from the floor.

The thermal efficiency of the installation was determined by calculating the globe temperature and humidity index (GTHI) proposed by Buffington et al. (1981Buffington, D. E., Collazo-Arocho, A., Canton, G. H., Pitt, D., Thatcher, W. W., & Collier, R. J. (1981). Black globe-humidity index (BGHI) as comfort equation for dairy cows. Transactions of the ASAE, 24(3), 711-714. DOI: https://doi.org/10.13031/2013.34325
https://doi.org/https://doi.org/10.13031... ), the temperature and humidity index (THI) proposed by Thom (1959Thom, E. C. (1959). The discomfort index. Weatherwise, 12(2), 57-61. DOI: https://doi.org/10.1080/00431672.1959.9926960
https://doi.org/https://doi.org/10.1080/... ), the radiant thermal load (RTL; W m^-2) proposed by Esmay (1982Esmay, M. L. (1982). Principles of Animal Environment (p. 325). Westport,CT: Avi Pub.) and the enthalpy (h; KJ kg^-1) proposed by Albright (1990Albright, L. D. (1990). Environment Control for Animals and Plants (ASAE Textbook, 4, p. 453). Michigan, US: American Society of Agricultural Engineers.).

The physiological variables recorded were rectal temperature (RT; ºC), respiratory rate (RR; mov min.^-1) and skin temperature (ST; ºC), twice a week in pre-milking, after acclimatization, at times from 0500h (morning period) and 1400h (afternoon period).

The RR variable was checked from the count of the number of movements of the flank region performed by the animal, in the interval of 1 min. After registration, RT measurements were performed, with the aid of a digital veterinary thermometer (scale between 20 and 50ºC), introduced into the rectum of the animals, for 1 min. for stabilization and obtaining the temperature value; the recording of RR and RT follows the recommendations of Almeida, Pandorfi, Guiselini, Henrique and Almeida (2011Almeida, G. L., Pandorfi, H., Guiselini, C., Henrique, H. M., & Almeida, G. A. (2011). Uso do sistema de resfriamento adiabático evaporativo no conforto térmico de vacas da raça girolando. Revista Brasileira de Engenharia Agrícola e Ambiental , 15(7), 754-760. DOI: https://doi.org/10.1590/S1415-43662011000700015
https://doi.org/https://doi.org/10.1590/... ) and Almeida et al. (2013Almeida, G. L., Pandorfi, H., Barbosa, S. B., Pereira, D. F., Guiselini, C., & Almeida, G. A. (2013). Comportamento, produção e qualidade do leite de vacas Holandês-Gir com climatização no curral. Revista Brasileira de Engenharia Agrícola e Ambiental , 17(8), 892-899. DOI: http://dx.doi.org/10.1590/S1415-43662013000800014
https://doi.org/http://dx.doi.org/10.159... ). The recording of ST was performed using an infrared thermometer, based on the temperature records of the head, back, shin and udder of each animal studied, for later determination of the average temperature of the skin according to the methodology established by Batista et al. (2021Batista, P. H. D., Almeida, G. L. P., Pandorfi, H., Silva, M. V., Silva, R. A. B., Silva, J. L. B., ... Moraes Rodrigues, J. A. (2021). Thermal images to predict the thermal comfort index for Girolando heifers in the Brazilian semiarid region. Livestock Science, 251, 104667. DOI: https://doi.org/10.1016/j.livsci.2021.104667
https://doi.org/https://doi.org/10.1016/... ).

Milk production (Prod) was determined individually, in the evaluated seasons, for the two daily milking periods. The chemical composition (fat - Fat, protein - Pro, lactose - Lac and total solids - Sol) was determined in two collections for each phase, with individual samples of the milk of each animal, in their respective treatments and analyzed in the Programa de Gerenciamento de Rebanhos Leiteiros do Nordeste (PROGENE), of the Animal Sciences Department at UFRPE.

The data were subjected to descriptive statistical analysis to obtain the mean, median and coefficient of variation (CV), classified as low when the CV < 12%; medium when 12% < CV < 24% and high when CV > 24% (Warrick & Nielsen, 1980Warrick, A. W., & Nielsen, D. R. (1980). Spatial variability of soil physical properties in the field. In D. HILLEL (Ed.), Applications of Soil Physics (Cap. 2, 319-344). New York, NY: Academic.). The Kolmogorov-Smirnov normality test (p ≤ 0.01) was also applied.

For the use of principal component analysis, 12 variables (h, THI, GTHI, RTL, RR, RT, ST, Prod, Fat, Pro, Lac, Sol) were considered for each season of the year (summer/winter), totaling 24 variables. From the principal components extracted from the data sets in the summer and winter seasons, the covariance matrix was obtained, in which the eigenvalues that originated the eigenvectors were extracted (Kaiser, 1958Kaiser, H. F. (1958). The varimax criterion for analytic rotation in factor analysis. Psychometrika, 23(3), 187-200. DOI: https://doi.org/10.1007/BF02289233
https://doi.org/https://doi.org/10.1007/... ).

This analysis was performed to identify parameters that explained most of the influence of the variables. For this, the Kaiser criterion was used, which considers eigenvalues above 1, because they generate components with a relevant amount of information contained in the original data, disregarding components that showed eigenvalues below 1 (Kaiser, 1958Kaiser, H. F. (1958). The varimax criterion for analytic rotation in factor analysis. Psychometrika, 23(3), 187-200. DOI: https://doi.org/10.1007/BF02289233
https://doi.org/https://doi.org/10.1007/... ).

Results and discussion

Morning period

Descriptive statistics for the morning period, in both seasons, are described in Table 1 and Table 2. The coefficient of variation (CV) was low for all variables studied, except milk fat (Fat) in winter, from animals subjected to 10 min. of cooling in pre-milking. The enthalpy (h) in winter, for the cooling times of 10 and 20 min. and, the respiratory rate (RR) in the summer, for the animals subjected to the control (0 min.), showed medium CV (12% < CV < 24 %).

The low values of the coefficient of variation indicate that the use of the evaporative adiabatic cooling system (EACS) proved to be efficient in homogenizing the environment in which the animals were. The THI values in both seasons, in the morning period, were lower than 72, characterized as a condition of comfort for the animals, as established by Armstrong (1994Armstrong, D. (1994). Heat stress interaction with shade and cooling. Journal of Dairy Science, 77(7), 2044-2050. DOI: https://doi.org/10.3168/jds.S0022-0302(94)77149-6
https://doi.org/https://doi.org/10.3168/... ).

Table 3 shows the principal components (PC) obtained through multivariate analysis, for comfort indices, physiological variables, production, and composition of milk of cows in the morning period (summer/winter). Components 1 (PC1) and 2 (PC2) showed an eigenvalue greater than 1, according to the criterion established by Kaiser (1958Kaiser, H. F. (1958). The varimax criterion for analytic rotation in factor analysis. Psychometrika, 23(3), 187-200. DOI: https://doi.org/10.1007/BF02289233
https://doi.org/https://doi.org/10.1007/... ), with eigenvalues on the order of 16.732 and 5.590, respectively. PC1 and PC2 had a total variance on the order of 93.00% for PC2.

Corroborating the results of the present study, Silva et al. (2021Silva, M. V., Pandorfi, H., Jardim, A. M. R. F., Oliveira-Júnior, J. F., Divincula, J. S., Giongo, P. R., ... Lopes, P. M. O. (2021b). Spatial modeling of rainfall patterns and groundwater on the coast of northeastern Brazil. Urban Climate, 38, 100911. DOI: https://doi.org/10.1016/j.uclim.2021.100911
https://doi.org/https://doi.org/10.1016/... a) evaluated the influence of abiotic variables on the behavioral patterns of dairy cows subjected to an adiabatic evaporative cooling system in a semiarid region of northeastern Brazil, for the dry and rainfall season, through the analysis of PCs, and observed a total variance in the correlation of the variables of 88.10 and 90.00% for the morning and afternoon periods, respectively.

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Table 1
Descriptive statistics of milk production (Prod, liters), fat (Fat, %), protein (Pro, %), lactose (Lac, %), total solids (Sol, %) in the morning period in both seasons.

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Table 2
Descriptive statistics of enthalpy (h, KJ kg^-1), black globe temperature and humidity index (GTHI), temperature and humidity index (THI), radiant thermal load (RTL, W m^-2), rectal temperature (RT, °C), respiratory rate (RR, mov min.^-1) and skin temperature (ST, °C) in the morning period in both seasons.

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Table 3
Principal components of comfort indices, physiological variables, behavioral parameters, and production and composition of milk of dairy cows in the morning period in summer and winter.

The thermal comfort indices and physiological variables showed a positive correlation for the morning period in summer and winter, except for the rectal temperature (RT), which was neutral, that is, without the influence of comfort indices (Table 3). This was due to the lower temperatures in the morning period, which were within the comfort range of the animals.

The negative association between the levels of protein, fat and total solids with milk production (Table 3) occurred due to greater dilution of protein, fat and total solids in milk, given the higher volume produced in the morning period (Table 1). Gabbi et al. (2018Gabbi, A. M., Mcmanus, C. M., Marques, L. T., Abreu, A. S., Machado, S. C., Zanela, M. B., ... Fischer, V. (2018). Different levels of supplied energy for lactating cows affect physicochemical attributes of milk. Journal of Animal and Feed Sciences, 27, 11-17. DOI: https://doi.org/10.22358/jafs/83703/2018
https://doi.org/https://doi.org/10.22358... ) also found the same negative relationship between protein, fat, and total solids. The relationship between fat and protein was already expected, as these variables have a positive relationship with each other (Macciotta, Cecchinato, Mele, & Bittante, 2012Macciotta, N. P. P., Cecchinato, A., Mele, M., & Bittante, G. (2012). Use of multivariate factor analysis to define new indicator variables for milk composition and coagulation properties in Brown Swiss cows. Journal of Dairy Science , 95(12), 7346-7354. DOI: https://doi.org/10.3168/jds.2012-5546
https://doi.org/https://doi.org/10.3168/... ; Mele et al., 2016Mele, M., Macciotta, N. P. P., Cecchinato, A., Conte, G., Schiavon, S., & Bittante, G. (2016). Multivariate factor analysis of detailed milk fatty acid profile: Effects of dairy system, feeding, herd, parity, and stage of lactation. Journal of Dairy Science , 99(12), 9820-9833. DOI: https://doi.org/10.3168/jds.2016-11451
https://doi.org/https://doi.org/10.3168/... ).

Figure 2 presents the PCs of the physiological variables, animal comfort indices, and production and composition of milk of cows subjected to EACS (0, 10, 20 and 30 min.) in the morning period (summer/winter).

Figure 2
Principal components of the physiological variables, animal comfort indices, and production and composition of milk of cows in the morning period in summer and winter (A); PCs of the operating time of the EACS in the morning (B). Note: h: enthalpy (h; KJ kg^-1); GTHI: globe temperature and humidity index; THI: temperature and humidity index; RTL: radiant thermal load (W m^-2); RT: rectal temperature (ºC); RR: respiratory rate (mov min^-1); ST: skin temperature (ºC); Prod: milk production (liters); Fat: fat (%); Pro: protein (%); Lac: lactose (%); Solid: soluble solids (%); EACS: adiabatic evaporative cooling system operating for times of 0, 10, 20 and 30 minutes.

The highest milk production (Prod) in the summer season was obtained for animals exposed to EACS for 30 min. in pre-milking. The longer exposure to EACS promoted better comfort, with improvements in thermal comfort indices and physiological variables (Table 1). It is noted in Figure 2A that the time of 30 min. is opposite to comfort indices and physiological variables, which occurs because the EACS time of 30 min. allows significant reductions in these variables, promoting thermal comfort for the animals, as observed by Silva et al. (2021Silva, M. V., Pandorfi, H., Jardim, A. M. R. F., Oliveira-Júnior, J. F., Divincula, J. S., Giongo, P. R., ... Lopes, P. M. O. (2021b). Spatial modeling of rainfall patterns and groundwater on the coast of northeastern Brazil. Urban Climate, 38, 100911. DOI: https://doi.org/10.1016/j.uclim.2021.100911
https://doi.org/https://doi.org/10.1016/... a). Silva and Passini (2018Silva, D. C., & Passini, R. (2018). Assessing different holding pen cooling systems through environmental variables and productivity of lactating cows. Acta Scientiarum. Animal Sciences, 40, e36087. DOI: https://doi.org/10.4025/actascianimsci.v40i1.36087
https://doi.org/https://doi.org/10.4025/... ) evaluated different cooling systems in the waiting room for crossbred cows (⅞ Holstein x ⅛ Dairy Gyr), using environmental variables, milk production, and economic indices in the summer in a tropical climate region, and observed similar results to those obtained in the present study, in which the evaporative adiabatic cooling time of 30 minutes provided the best comfort conditions for the animals.

In the winter season, in the morning period, the time of 10 min. of exposure of the animals to the EACS was sufficient for thermal conditioning, with a positive effect on milk production (Figure 2A and 2B).

PC1 was the one that best explained milk production due to the other variables (Figure 2A). Крамаренко et al. (2017Крамаренко, О. С., Крамаренко, А. С., Крамаренко, С. С., Крамаренко, С. С., Кузьмічова, Н. І., & Кузьмичёва, Н. И. (2017). Моделювання лактаційних кривих молочних корів за допомогою аналізу головних компонент (PCA). Вісник Аграрної Науки Причорномор'я, 4(96), 115-125.) evaluated the total yield of lactating cows through Principal Component Analysis (PCA) and observed that PC1 was sufficient to determine the potential level of yield of dairy cows.

The times of exposure of the animals to the EACS caused changes in the composition of the milk, according to the averages shown in Table 1. In contrast, Almeida et al. (2013Almeida, G. L., Pandorfi, H., Barbosa, S. B., Pereira, D. F., Guiselini, C., & Almeida, G. A. (2013). Comportamento, produção e qualidade do leite de vacas Holandês-Gir com climatização no curral. Revista Brasileira de Engenharia Agrícola e Ambiental , 17(8), 892-899. DOI: http://dx.doi.org/10.1590/S1415-43662013000800014
https://doi.org/http://dx.doi.org/10.159... ) concluded through analysis of variance and Tukey test that the use of different cooling times in the waiting pen in the summer season did not cause changes in the chemical composition of milk in the morning period. The same can be observed for the winter season (Figure 2A and 2B), in which the EACS influenced the composition of milk (Table 1). However, Almeida Neto, Pandorfi, ,Almeida, and Guiselini (2014Almeida Neto, L. A. D., Pandorfi, H., Almeida, G. L., & Guiselini, C. (2014). Climatização na pré-ordenha de vacas Girolando no inverno do semiárido. Revista Brasileira de Engenharia Agrícola e Ambiental, 18(10), 1072-1078. DOI: https://doi.org/10.1590/1807-1929/agriambi.v18n10p1072-1078
https://doi.org/https://doi.org/10.1590/... ), using classical statistics, found that different times of evaporative adiabatic cooling in winter, in a semi-arid region, did not lead to changes in milk composition. In view of these findings, it is observed that the application of multivariate analysis by PCs made it possible to extract results not previously observed based on classical/conventional statistics.

Garner et al. (2017Крамаренко, О. С., Крамаренко, А. С., Крамаренко, С. С., Крамаренко, С. С., Кузьмічова, Н. І., & Кузьмичёва, Н. И. (2017). Моделювання лактаційних кривих молочних корів за допомогою аналізу головних компонент (PCA). Вісник Аграрної Науки Причорномор'я, 4(96), 115-125.) observed that THI > 72 implied less milk production for Holstein cows. The results found by these authors corroborate that of the present study, in Figure 2A and 2B, which show that in the two seasons, milk production was inversely proportional to THI. However, it is noteworthy that in winter the THI values, even for the EACS 0 min. (control), were less than 68.00, and for the summer season the THI did not exceed 70.00 units, therefore, with little influence on milk production (Table 1).

Afternoon period

The coefficient of variation (CV) was low for all variables studied, except for milk fat (Fat) of the animals subjected to EACS for 30 min., for the respiratory rate (RR) of the animals at all cooling times, and for the skin temperature (ST) of the control animals in the summer season, which showed medium CV (12% < CV < 24%). In the winter season, the CV was medium for Fat among animals exposed to EACS for 30 min. and for ST at 0 and 10 min. (Table 4 and 5).

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Table 4
Descriptive statistics of milk production (Prod, liters), fat (Fat, %), protein (Pro, %), lactose (Lac, %), total solids (Sol, %) in the afternoon period in both seasons.

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Table 5
Descriptive statistics of enthalpy (h, KJ kg^-1), black globe temperature and humidity index (GTHI), temperature and humidity index (THI), radiant thermal load (RTL, W m^-2), rectal temperature (RT, °C), respiratory rate (RR, mov min.^-1) and skin temperature (ST, °C) in the afternoon period in both seasons.

The components PC1 and PC2 had eigenvalues greater than 1 (16.616 and 4.806), respectively. The PCs used in the discussion of variables showed a total variance of around 89.30% for PC2 (Table 6). Gabbi et al. (2018Gabbi, A. M., Mcmanus, C. M., Marques, L. T., Abreu, A. S., Machado, S. C., Zanela, M. B., ... Fischer, V. (2018). Different levels of supplied energy for lactating cows affect physicochemical attributes of milk. Journal of Animal and Feed Sciences, 27, 11-17. DOI: https://doi.org/10.22358/jafs/83703/2018
https://doi.org/https://doi.org/10.22358... ) related levels of total digestible nutrients and experimental period to milk production, composition, and quality, with Jersey, Jersey × Holstein, and Holstein cows, through the analysis of PCs and obtained results of the total variance of 87.24%, hence similar to those found in the present study.

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Table 6
Principal components of comfort indices, physiological variables, behavioral parameters, and production and composition of milk of dairy cows in the afternoon period in the summer and winter seasons.

According to the results observed in PC1, there was a relationship between protein and milk production and composition, as well as a positive correlation with thermal comfort index and physiological variables; however, no influence on the percentage of protein was observed in the afternoon period for the summer season (Table 6). Corroborating the results of the present study, Lambertz, Sanker, and Gauly (2014Lambertz, C., Sanker, C., & Gauly, M. (2014). Climatic effects on milk production traits and somatic cell score in lactating Holstein-Friesian cows in different housing systems. Journal of Dairy Science , 97, 319-329. DOI: https://doi.org/10.3168/jds.2013-7217
https://doi.org/https://doi.org/10.3168/... ), who evaluated the climatic effects on milk yield traits and somatic cell score in lactating Holstein cows in different housing systems, observed that the percentage of milk protein decreased under conditions of thermal stress, as the animals under conditions of discomfort reduce food consumption, a source that is fundamental for the concentration of protein in their milk.

Wildridge et al. (2018Wildridge, A. M., Thomson, P. C., Garcia, S. C., John, A. J., Jongman, E. C., Clark, C. E., & Kerrisk, K. L. (2018). The effect of temperature-humidity index on milk yield and milking frequency of dairy cows in pasture-based automatic milking systems. Journal of Dairy Science , 101(5), 4479-4482. DOI: https://doi.org/10.3168/jds.2017-13867
https://doi.org/https://doi.org/10.3168/... ) reported the existence of a delay in the animal's response from one to two days due to external weather conditions, identified by the THI. Thus, the non-influence on milk protein by comfort indices and physiological variables probably occurred in response to the better comfort conditions that the animals received in the morning period during pre-milking.

In Figure 3, the PCs of the physiological variables, animal comfort indices, milk production, and milk composition of animals subjected to EACS in the afternoon (summer/winter) are presented.

Figure 3
Principal components of the physiological variables, animal comfort indices, and production and composition of milk of cows in the afternoon period in summer and winter (A); PCs of the operating time of the EACS in the afternoon (B).

Note: h: enthalpy (h; KJ kg^-1); GTHI: globe temperature and humidity index; THI: temperature and humidity index; RTL: radiant thermal load (W m^-2); RT: rectal temperature (ºC); RR: respiratory rate (mov min.^-1); ST: skin temperature (ºC); Prod: milk production (liters); Fat: fat (%); Pro: protein (%); Lac: lactose (%); Solid: soluble solids (%); EACS: adiabatic evaporative cooling system operating for times of 0, 10, 20 and 30 minutes.

Unlike the morning period, in which the highest milk production in the summer was observed for animals exposed to EACS for 30 min., in the afternoon period it was observed that animals exposed to EACS for 10 min. had positive responses in milk production (Figure 2A and 2B and Figure 3A and 3B). In the winter season in the afternoon, the use of the EACS did not influence milk production (Table 4).

For the THI in both seasons (summer and winter), its values were higher in the afternoon period, exceeding the threshold of 72 (Table 5). Based on the findings by Wildridge et al. (2018Wildridge, A. M., Thomson, P. C., Garcia, S. C., John, A. J., Jongman, E. C., Clark, C. E., & Kerrisk, K. L. (2018). The effect of temperature-humidity index on milk yield and milking frequency of dairy cows in pasture-based automatic milking systems. Journal of Dairy Science , 101(5), 4479-4482. DOI: https://doi.org/10.3168/jds.2017-13867
https://doi.org/https://doi.org/10.3168/... ), who observed that the animal's response to conditions of comfort or heat stress is not immediate, with time spent for the animal to respond to that condition to which it was subjected. Therefore, it is safe to say that the response to the effect of air conditioning in the morning in both seasons may be related to improvements in milk production and composition in the afternoon. Thus, the effect of the air-conditioning in the afternoon period contributes to improvements in milk production and composition in the morning of the following day. As for animal comfort indices and physiological variables, the effect of EACS is immediate.

As for the composition of the milk, the cooling times promoted better results, with reductions in comfort indices and physiological variables (Figure 3).

Conclusion

The principal component analysis allowed us to identify the positive influence of evaporative cooling on thermal comfort, physiological responses, and production and composition of milk of lactating cows.

The winter season provided the best thermal comfort conditions for the animals. In the summer season, the 30-minute evaporative cooling time in the morning period increased milk production in the afternoon period. From the time of exposure of 10 minutes to evaporative cooling in the afternoon, there was an improvement in the productive performance of the animals in the morning milking of the following day.

Acknowledgements

To the Programa de Pós-Graduação em Engenharia Agrícola (PGEA) and the Grupo de Pesquisa em Ambiência (GPESA) of the Universidade Federal Rural de Pernambuco (UFRPE) for supporting this research. To the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES - Finance Code 001) and the Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco (FACEPE), for granting the scholarships.

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Publication Dates

Publication in this collection
09 Oct 2023
Date of issue
2023

History

Received
23 Oct 2021
Accepted
10 May 2022

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

[1] Albright, L. D. (1990). Environment Control for Animals and Plants (ASAE Textbook, 4, p. 453). Michigan, US: American Society of Agricultural Engineers.

[2] Almeida Neto, L. A. D., Pandorfi, H., Almeida, G. L., & Guiselini, C. (2014). Climatização na pré-ordenha de vacas Girolando no inverno do semiárido. Revista Brasileira de Engenharia Agrícola e Ambiental, 18(10), 1072-1078. DOI: https://doi.org/10.1590/1807-1929/agriambi.v18n10p1072-1078
» https://doi.org/https://doi.org/10.1590/1807-1929/agriambi.v18n10p1072-1078

[3] Almeida, G. L., Pandorfi, H., Barbosa, S. B., Pereira, D. F., Guiselini, C., & Almeida, G. A. (2013). Comportamento, produção e qualidade do leite de vacas Holandês-Gir com climatização no curral. Revista Brasileira de Engenharia Agrícola e Ambiental , 17(8), 892-899. DOI: http://dx.doi.org/10.1590/S1415-43662013000800014
» https://doi.org/http://dx.doi.org/10.1590/S1415-43662013000800014

[4] Almeida, G. L., Pandorfi, H., Guiselini, C., Henrique, H. M., & Almeida, G. A. (2011). Uso do sistema de resfriamento adiabático evaporativo no conforto térmico de vacas da raça girolando. Revista Brasileira de Engenharia Agrícola e Ambiental , 15(7), 754-760. DOI: https://doi.org/10.1590/S1415-43662011000700015
» https://doi.org/https://doi.org/10.1590/S1415-43662011000700015

[5] Alvares, C. A., Stape, J. L., Sentelhas, P. C., Moraes Gonçalves, J. L., & Sparovek, G. (2013). Köppen's climate classification map for Brazil. Meteorologische Zeitschrift, 22(6), 711-728. DOI: https://doi.org/10.1127/0941-2948/2013/0507
» https://doi.org/https://doi.org/10.1127/0941-2948/2013/0507

[6] Agência Pernambucana de Águas e Climas [APAC]. (2019). Monitoramento pluviométrico Retrieved from http://www.apac.pe.gov.br/meteorologia/monitoramento-pluvio.php
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[7] Armstrong, D. (1994). Heat stress interaction with shade and cooling. Journal of Dairy Science, 77(7), 2044-2050. DOI: https://doi.org/10.3168/jds.S0022-0302(94)77149-6
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¹Var	²Tim	Summer					Winter
¹Var	²Tim	³m	⁴SD	⁵CV	⁶Min	⁷Max	m	SD	CV	Min	Max
Prod	0	10.84	0.63	5.80	9.91	11.30	11.69	0.73	6.26	10.84	12.62
	10	11.08	0.37	3.34	10.75	11.59	11.77	0.38	3.23	11.42	12.26
	20	11.36	0.16	1.41	11.21	11.58	11.77	0.96	8.18	11.07	13.18
	30	11.54	0.48	4.20	11.04	12.20	11.74	0.96	8.20	10.45	12.62
Fat	0	3.08	0.22	7.19	2.85	3.35	3.01	0.26	8.72	2.63	3.19
	10	2.64	0.23	8.77	2.39	2.86	3.00	0.40	13.24	2.62	3.55
	20	2.88	0.34	11.80	2.41	3.19	2.99	0.35	11.53	2.59	3.34
	30	2.74	0.31	11.36	2.37	3.02	3.10	0.25	8.04	2.73	3.27
Pro	0	2.71	0.14	5.13	2.52	2.84	2.75	0.09	3.17	2.63	2.83
	10	2.69	0.10	3.57	2.60	2.82	2.74	0.09	3.40	2.61	2.81
	20	2.71	0.05	1.83	2.64	2.76	2.76	0.06	2.20	2.67	2.80
	30	2.66	0.06	2.14	2.58	2.71	2.79	0.06	1.98	2.72	2.85
Lac	0	4.42	0.11	2.48	4.34	4.58	4.56	0.11	2.32	4.43	4.65
	10	4.50	0.15	3.28	4.36	4.70	4.61	0.06	1.40	4.54	4.67
	20	4.51	0.12	2.69	4.41	4.69	4.60	0.05	1.08	4.53	4.65
	30	4.52	0.12	2.58	4.39	4.67	4.61	0.11	2.43	4.50	4.76
Sol	0	11.11	0.19	1.68	10.91	11.27	11.25	0.14	1.28	11.06	11.39
	10	10.72	0.10	0.93	10.61	10.81	11.28	0.41	3.60	10.97	11.88
	20	10.96	0.32	2.93	10.56	11.32	11.28	0.34	3.03	10.83	11.64
	30	10.82	0.35	3.25	10.36	11.16	11.43	0.18	1.58	11.19	11.62

¹Var	²Tim	Summer					Winter
¹Var	²Tim	³m	⁴SD	⁵CV	⁶Min	⁷Max	m	SD	CV	Min	Max
h	0	60.30	1.54	2.55	58.10	61.50	54.42	2.03	3.73	51.90	56.80
	10	58.33	1.16	1.98	57.10	59.70	50.55	6.58	13.02	41.10	55.20
	20	57.93	1.41	2.43	56.70	59.90	49.73	6.43	12.94	40.40	54.10
	30	57.45	1.02	1.78	56.20	58.70	52.33	1.54	2.94	50.20	53.60
GTHI	0	69.25	0.50	0.72	69.00	70.00	64.75	0.96	1.48	64.00	66.00
	10	68.00	0.00	0.00	68.00	68.00	64.00	0.82	1.28	63.00	65.00
	20	67.50	0.58	0.86	67.00	68.00	63.50	0.58	0.91	63.00	64.00
	30	67.50	0.58	0.86	67.00	68.00	63.50	0.58	0.91	63.00	64.00
THI	0	70.00	0.00	0.00	70.00	70.00	67.00	0.82	1.22	66.00	68.00
	10	69.00	0.00	0.00	69.00	69.00	66.00	1.41	2.14	64.00	67.00
	20	68.75	0.50	0.73	68.00	69.00	65.75	1.50	2.28	64.00	67.00
	30	68.00	0.00	0.00	68.00	68.00	65.75	0.50	0.76	65.00	66.00
RTL	0	420.35	6.16	1.47	411.80	426.50	381.32	11.26	2.95	367.70	392.30
	10	401.90	14.83	3.69	385.60	420.30	352.60	26.80	7.60	317.50	376.70
	20	396.60	23.50	5.94	364.60	419.40	359.80	30.20	8.39	319.50	387.80
	30	407.60	10.57	2.59	394.30	420.10	348.90	23.40	6.70	323.10	376.50
RT	0	38.18	0.13	0.33	38.00	38.30	38.03	0.22	0.58	37.80	38.30
	10	38.28	0.05	0.13	38.20	38.30	38.15	0.10	0.26	38.00	38.20
	20	38.15	0.17	0.45	38.00	38.30	38.13	0.19	0.50	38.00	38.40
	30	38.03	0.15	0.39	37.90	38.20	37.95	0.10	0.26	37.90	38.10
RR	0	36.00	4.76	13.22	33.00	43.00	28.00	1.41	5.05	26.00	29.00
	10	27.75	1.26	4.53	26.00	29.00	26.50	2.65	9.98	24.00	30.00
	20	28.00	2.71	9.67	26.00	32.00	26.75	2.22	8.29	24.00	29.00
	30	25.75	1.26	4.89	24.00	27.00	26.00	2.83	10.88	22.00	28.00
ST	0	30.08	0.94	3.12	29.20	31.30	26.70	1.51	5.65	25.10	28.60
	10	27.70	0.92	3.32	26.60	28.60	26.58	1.14	4.31	25.60	28.20
	20	26.68	0.85	3.17	25.60	27.40	25.70	0.08	0.32	25.60	25.80
	30	26.45	0.79	2.97	25.40	27.10	24.95	2.25	9.01	22.60	28.00

Variable	Principal Component in Summer		Principal Component in Winter
Variable	*PC1	PC2	PC1	PC2
¹h	0.244	-0.017	0.165	-0.298
²GTHI	0.239	-0.077	0.242	-0.032
³THI	0.239	0.026	0.225	-0.112
⁴RTL	0.184	-0.259	0.234	-0.043
⁵RT	0.121	0.338	0.033	0.417
⁶RR	0.242	-0.041	0.240	0.013
⁷ST	0.239	-0.027	0.196	0.220
⁸Prod	-0.227	-0.111	-0.196	0.251
⁹Fat	0.192	-0.125	-0.118	-0.355
¹⁰Pro	0.191	0.208	-0.134	-0.342
¹¹Lac	-0.242	0.053	-0.234	0.094
¹²Sol	0.182	-0.125	-0.178	-0.281
Eigenvalue	16.732	5.590	16.732	5.590
Proportion	0.697	0.233	0.697	0.233
Accumulated	0.697	0.930	0.697	0.930

¹Var	²Tim	Summer					Winter
¹Var	²Tim	³m	⁴SD	⁵CV	⁶Min	⁷Max	m	SD	CV	Min	Max
Prod	0	6.67	0.29	4.40	6.35	6.98	7.67	0.62	8.06	6.83	8.21
	10	6.89	0.26	3.72	6.67	7.20	7.61	0.37	4.81	7.20	7.98
	20	6.75	0.29	4.30	6.39	7.04	7.61	0.35	4.63	7.20	7.94
	30	6.87	0.19	2.78	6.63	7.09	7.70	0.54	7.07	7.08	8.18
Fat	0	4.15	0.42	10.21	3.55	4.49	4.34	0.27	6.10	4.14	4.71
	10	4.69	0.55	11.66	4.11	5.32	4.31	0.44	10.30	3.74	4.74
	20	4.14	0.31	7.51	3.79	4.53	4.46	0.15	3.33	4.29	4.59
	30	4.40	0.61	13.95	3.72	5.11	4.44	0.59	13.26	4.03	5.29
Pro	0	2.71	0.17	6.32	2.45	2.82	2.79	0.08	2.91	2.67	2.84
	10	2.67	0.13	4.77	2.55	2.85	2.79	0.09	3.14	2.66	2.87
	20	2.72	0.07	2.44	2.64	2.80	2.79	0.04	1.34	2.74	2.82
	30	2.68	0.10	3.60	2.55	2.77	2.82	0.09	3.06	2.70	2.88
Lac	0	4.41	0.12	2.79	4.33	4.59	4.47	0.03	0.76	4.43	4.51
	10	4.42	0.13	2.87	4.28	4.59	4.53	0.03	0.77	4.49	4.57
	20	4.44	0.06	1.42	4.38	4.53	4.52	0.05	1.01	4.47	4.56
	30	4.43	0.14	3.09	4.30	4.60	4.51	0.07	1.65	4.46	4.62
Sol	0	12.19	0.40	3.26	11.61	12.50	12.54	0.33	2.65	12.23	13.01
	10	12.70	0.59	4.63	11.97	13.39	12.57	0.52	4.14	11.90	13.10
	20	12.22	0.38	3.12	11.81	12.68	12.72	0.23	1.80	12.44	12.97
	30	12.45	0.59	4.73	11.68	12.98	12.71	0.68	5.36	12.15	13.69

¹Var	²Tim	Summer					Winter
¹Var	²Tim	³m	⁴SD	⁵CV	⁶Min	⁷Max	m	SD	CV	Min	Max
h	0	70.65	2.23	3.16	68.40	72.90	65.93	1.73	2.63	63.50	67.60
	10	69.03	1.04	1.51	68.10	70.20	64.78	2.38	3.67	61.60	66.70
	20	67.63	0.96	1.42	66.80	69.00	62.72	2.50	3.99	60.40	65.80
	30	66.38	1.20	1.81	64.70	67.30	64.00	2.34	3.65	60.70	65.80
GTHI	0	82.25	2.50	3.04	79.00	85.00	75.75	1.89	2.50	73.00	77.00
	10	72.25	0.50	0.69	72.00	73.00	69.50	1.92	2.76	67.00	71.00
	20	71.50	0.58	0.81	71.00	72.00	69.00	1.41	2.05	67.00	70.00
	30	71.25	0.50	0.70	71.00	72.00	68.75	1.26	1.83	67.00	70.00
THI	0	77.75	1.26	1.62	76.00	79.00	74.50	0.58	0.77	74.00	75.00
	10	75.25	0.96	1.27	74.00	76.00	73.00	1.16	1.58	72.00	74.00
	20	73.50	1.00	1.36	72.00	74.00	72.25	0.96	1.33	71.00	73.00
	30	73.00	0.82	1.12	72.00	74.00	72.00	0.82	1.13	71.00	73.00
RTL	0	534.40	31.00	5.80	503.20	573.20	482.60	28.80	5.98	443.40	508.20
	10	388.32	8.85	2.28	379.30	399.30	353.70	40.10	11.34	313.80	396.70
	20	390.32	7.15	1.83	380.10	395.30	348.10	33.30	9.55	315.20	391.30
	30	397.45	5.48	1.38	390.40	403.10	347.40	32.50	9.36	317.10	389.30
RT	0	39.05	0.24	0.61	38.80	39.30	38.95	0.24	0.61	38.70	39.20
	10	38.93	0.21	0.53	38.70	39.10	38.73	0.21	0.53	38.50	39.00
	20	38.90	0.28	0.73	38.70	39.30	38.75	0.30	0.77	38.60	39.20
	30	38.73	0.15	0.39	38.50	38.80	38.63	0.17	0.44	38.40	38.80
RR	0	61.50	12.12	19.71	51.00	79.00	51.75	9.74	18.83	41.00	60.00
	10	38.75	7.41	19.12	32.00	47.00	38.75	7.14	18.41	30.00	47.00
	20	39.75	9.18	23.09	29.00	50.00	33.75	3.10	9.17	31.00	38.00
	30	35.25	7.14	20.24	27.00	44.00	31.50	3.11	9.87	28.00	35.00
ST	0	38.50	5.09	13.22	33.20	45.30	34.23	2.18	6.38	31.70	36.80
	10	31.93	1.27	3.98	30.10	33.00	30.15	0.70	2.31	29.50	31.10
	20	29.83	1.90	6.38	27.60	32.10	28.43	0.64	2.25	27.60	29.10
	30	30.78	2.07	6.73	27.80	32.60	29.48	0.91	3.08	28.60	30.60

Variable	Principal Component in Summer		Principal Component in Winter
Variable	*PC1	PC2	PC1	*PC1
¹h	0.229	0.113	0.203	0.191
²GTHI	0.242	-0.060	0.243	-0.034
³THI	0.241	0.070	0.241	0.083
⁴RTL	0.233	-0.103	0.239	-0.075
⁵RT	0.204	0.078	0.240	-0.061
⁶RR	0.241	-0.089	0.244	0.036
⁷ST	0.240	0.004	0.236	0.025
⁸Prod	-0.181	0.282	0.027	-0.132
⁹Fat	-0.086	0.423	-0.150	-0.360
¹⁰Pro	0.059	-0.413	-0.160	-0.125
¹¹Lac	-0.218	-0.181	-0.197	0.201
¹²Sol	-0.101	0.413	-0.204	-0.251
Eigenvalue	16.616	4.806	16.616	4.806
Proportion	0.692	0.200	0.692	0.200
Accumulated	0.692	0.893	0.692	0.893