EFFECT OF ATMOSPHERIC TEMPERATURE ON BLOOD CHANGES OF TOTAL OXIDATIVE STRESS INDEX, (OSI) AND LIPID PROFILE IN PERIPARTUM EWES

Authors

1 Biochemistry and Nutritional Deficiency Diseases Unit., Animal Health Research Institute, Assiut Branch, Agriculture Research Center, Egypt

2 Animal Production Research Institute- Sheep and Goat Research Department.

Abstract

Oxidative stress index (OSI) is recently used as a valid tool for providing an in depth picture about redox status and oxidative stress. The study was conducted on Fourteen multiparous, singleton bearing Osimi ewes (1.5-2 years, 35-40 kg) belonging to agriculture research station, Assiut district, A.R. Egypt during spring (as controls, N=7) and during summer (as heat stressed, N=7). Ewes were blood sampled weekly throughout the last three weeks prepartum and weekly throughout the first three weeks post-lambing for determination of blood serum lipids and oxidative stress biomarkers. Results showed increased blood serum total cholesterol, triglycerides, high density lipoprotein (HDL) and low density lipoprotein LDL (p < 0.05) before lambing and then decreased (p < 0.05) after lambing. Total Cholesterol, triglycerides and HDL was lower (p < 0.05) in summer compared to spring. In spring and summer, total peroxide (TPX) increased at the first week (p < 0.05) before and after lambing in addition to summer values were higher (p < 0.05) than spring values. In spring, total antioxidant capacity (TAC) increased at the second week (p < 0.05) after lambing, whereas a reverse trend was noticed in summer season, so that summer TAC values were lower (p < 0.05) than spring values. Pearson's Product Moment Correlation between TPX and TAC did not reveal significant indication. However, values of oxidative stress index (OSI= TPX / TAC) x100  progressively increased (p < 0.05) in summer and reached its maximal value at the first week after lambing, then steadily decreased until reached the basal data at the third week after lambing. Summer TPX values were higher (p < 0.05) than spring values. This study is the first to evaluate the degree of OS in HS ewes during the peripartum period by detection of TPX, TAC and OSI values. Our data clarified that the maximal oxidative stress occurred at the first week after parturition that was associated with an increase of pro-oxidants rather than reduction of antioxidants during spring. Instead, both the increase in pro-oxidants and the reduction of antioxidants are sharing in the oxidative stress in summer.
 

Keywords

Main Subjects


Assiut University web-site: www.aun.edu.eg

 

EFFECT OF ATMOSPHERIC TEMPERATURE ON BLOOD CHANGES OF TOTAL OXIDATIVE STRESS INDEX, (OSI) AND LIPID PROFILE

IN PERIPARTUM EWES

 

GHADA A.E. MOHAMEDand HAYAM M. A. MONZALY 2

1 Animal Health Research Institute, Assiut Branch- Biochemistry and Nutritional Deficiency Diseases Unit.

2 Animal Production Research Institute- Sheep and Goat Research Department.

 

Received: 26 March 2019;     Accepted: 30 April 2019

 

 

ABSTRACT

 

Oxidative stress index (OSI) is recently used as a valid tool for providing an in depth picture about redox status and oxidative stress. The study was conducted on Fourteen multiparous, singleton bearing Osimi ewes (1.5-2 years, 35-40 kg) belonging to agriculture research station, Assiut district, A.R. Egypt during spring (as controls, N=7) and during summer (as heat stressed, N=7). Ewes were blood sampled weekly throughout the last three weeks prepartum and weekly throughout the first three weeks post-lambing for determination of blood serum lipids and oxidative stress biomarkers. Results showed increased blood serum total cholesterol, triglycerides, high density lipoprotein (HDL) and low density lipoprotein LDL (p<0.05) before lambing and then decreased (p<0.05) after lambing. Total Cholesterol, triglycerides and HDL was lower (p<0.05) in summer compared to spring. In spring and summer, total peroxide (TPX) increased at the first week (p<0.05) before and after lambing in addition to summer values were higher (p<0.05) than spring values. In spring, total antioxidant capacity (TAC) increased at the second week (p<0.05) after lambing, whereas a reverse trend was noticed in summer season, so that summer TAC values were lower (p<0.05) than spring values. Pearson's Product Moment Correlation between TPX and TAC did not reveal significant indication. However, values of oxidative stress index (OSI= TPX / TAC) x100  progressively increased (p<0.05) in summer and reached its maximal value at the first week after lambing, then steadily decreased until reached the basal data at the third week after lambing. Summer TPX values were higher (p<0.05) than spring values. This study is the first to evaluate the degree of OS in HS ewes during the peripartum period by detection of TPX, TAC and OSI values. Our data clarified that the maximal oxidative stress occurred at the first week after parturition that was associated with an increase of pro-oxidants rather than reduction of antioxidants during spring. Instead, both the increase in pro-oxidants and the reduction of antioxidants are sharing in the oxidative stress in summer.

 

Key words: Ewes-Lactation-pregnancy-heat stress- lipid profile.

 

 

 

INTRODUCTION

 

High environmental temperatures in tropical and subtropical areas challenge the animal's ability to maintain the balance of its body (Silanikove, 2000). An imbalance between metabolic heat production inside the animal body and its dissipation to the surroundings results to heat stress (McKinley, et al., 2017). Heat stress (HS) reduces the metabolic rates and alters post-absorptive metabolism, regardless of the decreased feed intake (Baumgard and Rhoads, 2013; Sejian et al., 2018). It also suppresses the immune and endocrine system, thereby enhances susceptibility of an animal to various diseases and health problems (Das et al., 2016).  Therefore,   determining   the   energetic   of

 

 


Corresponding author: Dr. GHADA A.E. MOHAMED

E-mail address: dr_kada2012@yahoo.com

Present address: Animal Health Research Institute, Assiut Branch- Biochemistry and Nutritional Deficiency Diseases Unit.

heat-stressed animals would presumably provide evidence on how to better treat animals suffering from heat-related illnesses (Johnson et al., 2015, Lees et al., 2017).

 

Recently, it has been shown that heat stress disturbs the steady state concentrations of free radicals, resulting in both cellular and mitochondrial oxidative damage (Pandey et al., 2012). Belhadj     et al. (2014) qualified heat stress as cytotoxic, as it alters biological molecules, disturbs cell functions, modulates metabolic reactions, induces oxidative cell damage and activates both of apoptosis and necrosis pathways. The drastic effects of HS depend on its duration and severity (Belhadj et al., 2016).

 

Lipids especially polyunsaturated fatty acids are sensitive to oxidation forming a complex series of compounds, leading to the term lipid peroxidation (Halliwell & Gutteridge, 2017). Recent studies showed that the use of oxidative stress markers as a measure of oxidant-antioxidant balance could provide complementary information about the homeostasis of the animal than conventional metabolic parameters alone (Gutteridge & Halliwell, 2018).

 

Since the measurement of different oxidant molecules separately is not practical and their oxidant effects are additive, the total oxidant status of a sample is measured and this is named total peroxide (TPX) (Erel, 2005).

 

Serum concentrations of antioxidants can be measured separately in the laboratory, but these measurements are time-consuming, labor intensive and costly. Since the effects of the antioxidant components in serum are additive, measurement of the (TAC) accurately reflects the redox status of the serum (Halliwell & Gutteridge, 2017; Gutteridge & Halliwell, 2018).

 

Abuelo, et al. (2013) introduced the term Oxidative Stress Index (OSI), based on the ratio between TPX and serum TAC, that is, (TPX/ TAC), comparing the information given by this parameter with those given by TPX and TAC separately. Under the conditions of oxidative stress, the OSI provides an objective assessment of the relationship between oxidants and antioxidants, not seen by the determination of both components separately. An increase in TPX/ TAC ratio indicates a higher risk for OS because of an increase in ROS production, defensive antioxidant consumption, or both.

 

Pregnancy is a physiological process characterized by a drastic increase in energetic and oxygen demands, to ensure an adequate fetal development and growth, thus, both mother and fetus are likely to experience oxidative stress, during pregnancy (Mutinati et al., 2013). The transition peripartum period is a critical phase and particularly important for health of dairy animals (Ingvartsen and Andersen, 2000). The high metabolic demand in late pregnancy and early lactation period may also induce oxidative stress (Fassah et al., 2015).

 

There is a lack of information concerning the interaction between oxidative and antioxidant status in periparturient ewes especially under Upper Egypt conditions. In addition, determination of serum TPX and TAC with calculation of OSI value have not been used in ewes, especially under different production and reproduction phase. The nature of this mechanism still indistinct and the significance of their levels remain unclear. Therefore, the goal of this study was to document the effect of HS on the changes in lipid profile as a biomarker of energy metabolism, in addition to evaluation of redox balance. The redox included TPX as a biomarker of oxidants and TAC as a biomarker of antioxidant status in the peripartum ewes reared in winter and summer seasons. Further, to evaluate the oxidative stress by the estimation of OSI based on the ratio between TPX and the TAC during the late pregnancy and early lactation periods in ewes.

 

MATERIALS AND METHODS

 

The study was carried out at. Agriculture research station, Assiut district, A.R. Egypt. And done during March and April (representing spring, the thermoneutral zone) and July and August (representing mid-Summer; the hot period). Weather data were obtained from the local weather station. Briefly, in summer, this area is characterized by intensified air temperature, intensified sun radiation, long sunshine duration and low relative humidity, while in spring it is relatively thermoneutral Rainfall is almost negligible. The recorded arithmetic means of ambient air temperature and relative humidity during spring was 24˚C, 36% respectively, whereas during mid-Summer they were 44.13˚C, 27%, respectively.

 

Animals:

Fourteen multiparous, singleton bearing Osimi ewes (1.5-2 years, 35-40 kg). Clinically healthy were used during spring (as controls, N=7) and during summer (as heat stressed, N=7). During spring, ewes allowed to graze on Egyptian clover pasture (Trifolium Alexanderinum). During summer, clover hay and silage were offered in addition to grazing on medium-to-low quality forages including crop stubbles and green fodder. During the peripartum period, in addition, concentrate mixture was offered (250 gm/ewe) consisting of (24% yellow corn, 38% cotton- seed meal, 34% wheat bran, 3% molasses and 1% salt). The selected animals were subjected to standard methods of clinical examinations to prove their fitness.

 

Blood sampling:

Blood was sampled by jugular vein puncture into 10-ml clean test tubes without anticoagulant Sampling was carried out weekly throughout the last three weeks pre- partum and weekly throughout the first three weeks post-lambing. The accurate estimation of the day of pre partum sampling was assessed in relation to the lambing time. Blood samples were centrifuged at 3000 rpm for 15 minutes to obtain serum, which was kept at –20°C until be used for biochemical assay.

 

Biochemical analysis:

Blood serum lipid profile:

Total cholesterol (TC), Triglycerides (Trig) and High- density lipoprotein cholesterol (HDL) were measured using the standardized kit (Biodiagnostic, Dokki- Giza - Egypt), after the methods described by Richmond (1973), Fossati & Prencipe (1982) and Burstein et al. (1970), respectively. Low-density lipoprotein cholesterol (LDL) was calculated by using the Friedewald formula (Friedewald et al. 1972) as following: LDL-C = TC - (HDL-C + triglycerides/5).

 

Blood serum Total Antioxidant Capacity (TAC) concentration:

Total antioxidant capacity was measured using the standardized kit (Biodiagnostic, Dokki- Giza - Egypt), based on the reaction of antioxidants in the sample with a defined amount of exogenously provide hydrogen peroxide (H2O2). The antioxidants in the sample eliminate a certain amount of the provided hydrogen peroxide. The residual H2O2 is determined colorimetrically by an enzymatic reaction which involves the conversion of 3,5, dichloro-2-hydroxy benzensulphonate (ABTS) to a colored product. This has a relatively stable blue-green colour which is measured at 600 nm. For accuracy and reproducibility control, total antioxidant control was used after the method described by Koracevic et al. (2001).

 

Blood serum Total Peroxide (TPX) concentration:

Blood serum TPX concentration was measured as a H2O2 equivalent after the method described by (Erel, 2005). This method based on the oxidation of ferrous iron (as a catalyst) to ferric iron by the various types of plasma peroxides in the presence of xylenol orange in an acidic medium, which binds with iron(III) and forms a colored complex whose absorbance can be measured at 560 nm.

 

Oxidative stress index (OSI):

To perform the calculation, the OSI value was calculated using the following formula: OSI = [(TOS, umol/L) / (TAC, mmol equivalent/L) x100] according to Erel (2005).

 

Statistical analysis:

The results were analyzed by analysis of variance (ANOVA) followed by student "t" test for the comparison between seasons. F test followed by pair-wise comparisons (Duncan's new multiple range test) were used for the comparison between periods within the peripartum period of each season. Pearson Product Moment Correlation (PPMC) was performed on paired data obtained by individual cases for TPX and TAC. Data correlation (r), linear regression analysis (R2) and significance level (P-value) were estimated. The computer packaged software program SPSS was used for analysis according to (SPSS, 2002). Significance level was set at P < 0.05.

 

RESULTS

 

The recorded mean ambient temperature and relative humidity in spring was 24˚C, 36% respectively, whereas during mid-Summer they were 44.13˚C, 27%, respectively. The mean value (±SE) of rectal temperature ˚C of ewes was 38.91±0.08 and 39.47±0.07 in spring and mid-summer respectively. The values significantly differ at (P>0.05).

 

Blood serum total cholesterol concentration in spring was significantly increased at the first week (p<0.05) before lambing, then significantly decreased (p<0.05) at the first week (p<0.05) after lambing and returned to the base line level in the second and third weeks. In summer, it was significantly decreased at the first week (p<0.05) before lambing, and at the second week (p<0.05) after lambing. The values were significantly lower in summer at the first week prepartum and the second week postpartum when compared with the spring values (Tab. 1, Fig. 1).

 

In spring, Blood serum triglyceride concentration was significantly increased at the first week            (p<0.05) before lambing, then significantly decreased (p < 0.05) at the first week (p<0.05) after lambing and returned to the base line level in the second and third weeks. In summer, it was significantly decreased at the second week (p<0.05) before lambing, and at the first week (p<0.05) after lambing. The values were significantly lower at the first and second weeks prepartum and the first week postpartum when compared with the spring values (Tab. 1, Fig. 1).

 

Blood serum HDL concentrations in spring were significantly increased at the first week (p<0.05) before lambing, and then significantly decreased (p<0.05) at the third week (p<0.05) after lambing. In summer, HDL concentration was significantly decreased at the third week (p<0.05) after lambing. .The values were significantly lower in summer at the first week prepartum and the first week postpartum when compared with the spring values (Tab. 2, Fig. 2).

 

In spring, LDL concentration was significantly decreased at the second week (p<0.05) after lambing and significantly increase first week before lambing. In summer, LDL concentration was significantly increased at the first week (p<0.05) before lambing, and decrease at the second and third weeks (p<0.05) after lambing. Season had no significant effect on LDL concentrations (Tab. 2, Fig. 2).

 

In spring and summer, blood serum TPX concentration was significantly increased at the first week (p<0.05) before and after lambing and continued at a high level (p< 0.05) during the second week (p<0.05) after lambing then decreased to the baseline values at the remaining period. However, summer values were significantly higher (p<0.05) than spring values during the first week (p<0.05) before as well as the first week after lambing (Tab. 3, Fig. 3).

Blood serum Concentrations of TAC in spring increased at the second week (p<0.05) after lambing. A reverse trend was noticed in summer season, where the values were decreased at the first week before lambing and continued at low level during the first and second weeks after lambing when compared with the base line data. Summer values were significantly lower (p<0.05) than spring values during the first week (p<0.05) before as well as the first week after lambing (Tab. 3, Fig. 3).

 

Values of OSI in ewes progressively increased (p < 0.05) during the peripartum period at summer and reached its maximal value at the first week after lambing, then steadily decreased till reached the basal data at the third week after lambing. Summer values were significantly higher (p<0.05) than spring values during the first week (p<0.05) before as well as the first and second week after lambing (Tab. 3, Fig. 4).

 

Pearson’s correlation and regression analysis of TPX (as a representative value of the by-product of oxidative stress) with TAC (as a representative value of defense antioxidants) is presented in Fig. (4A). Linear regression analysis (R2) and Pearson’s correlation (r) of the paired data obtained by the individual cases did not reveal significant correlation between TPX and TAC (r = - 0.09, R2 = 0.017 and P = 0.601).

 

 

 

 

 

Fig. 1: Mean value of blood serum Total cholesterol and Triglycerides in ewes during the peripartum period at spring and summer (N=7).

a, b, c Duncan’s multiple row test: different letters within the same season indicate significantly different results (p<0.05)

* Within up down bars indicate significant different values between seasons

 

 

 

Fig. 2: Mean value of blood serum HDL and LDL in ewes during the peripartum period at spring and summer (N=7).

a, b, c Duncan’s multiple row test: different letters within the same season indicate significantly different results (p<0:05)

* Within up down bars indicate significant different values between seasons

 

 

 

Fig. 3: Mean value of blood serum TPX (umol/L) and TAC (mmol/L) in ewes during the peripartum period at spring and summer (N=7).

a, b: Duncan’s multiple row test: different letters within the same season indicate significantly different results (p<0:05)

* Within up down bars indicate significant different values between seasons.

 

 

 

Fig. 4. A: Pearson’s correlation (r), Linear regression (R2) analysis (of paired data obtained from individual ewes in both seasons, (N = 84) of the enhanced TPX and TAC concentrations.

B: Mean value of OSI in ewes during the peripartum period at spring and summer. a, b, c Duncan’s multiple row test: different letters within the same season indicate significantly different results (p<0.05). * Within up down bars indicate significant different values between seasons

 

Table 1: Mean value (±SE) of blood serum total cholesterol (mg/dl) and triglycerides (mg/dl) in ewes during the peripartum period at spring (N=7) and summer (N=7).

 

Parameter

Season

Weeks before lambing

Weeks after lambing

-3

-2

-1

1

2

3

Total Cholesterol

Spring

69.49±5.8a

73.35±5.1 ab

77.60±13.5 b*

55.59±7.7 c

55.21±5.1 c*

53.66±5.4 c

Summer

65.25±5.9 a

68.72±4.9 a

54.82±4.3 b

52.12±8.5 bc

42.47±6.2 c

47.87±3.1 bc

Triglycerides

Spring

38.94±3.3 a

40.71±4.4 ab*

46.02±4.2 b*

36.29±1.8 c*

37.17±2.5 ac

42.48±1.7 a

Summer

36.29±3.5 a

30.98±4.2 ab

37.17±4.1 a

27.44±1.7 b

32.75±2.6 a

37.17±1.6 a

a, b, c Duncan’s multiple row test: different letters within the same season indicate significantly different results (p<0:05)

* Indicate significant different values between seasons

Table 2: Mean value (±SE) of blood serum HDL (mg/dl) and LDL (mg/dl) in ewes during the peripartum period at spring (N=7) and summer (N=7).

 

Parameter

Season

Weeks before lambing

Weeks after lambing

-3

-2

-1

1

2

3

HDL

Spring

30.50±2.7 a

30.89±3.1 ab

33.59±2.7 b*

28.96±4.6 ac*

25.87±2.7 ac

24.71±3.1c

Summer

26.25±2.8 a

28.19±1.9 a

27.41±2.3 a

23.17±5.8 ab

22.39±3.8 ab

21.24±1.5 b

LDL

Spring

35.14±3.4 a

37.45±3.8 ab

45.95±3.8 b

33.98±3.4 ac

29.73±2.7 c

32.05±2.7 ac

Summer

31.66±3.6 a

34.36±3.4 ab

38.22±2.7 b

30.50±2.9 ac

29.34±3.9 c

29.73±1.9 c

a, b, c Duncan’s multiple row test: different letters within the same season indicate significantly different results (p<0.05)

* Indicate significant different values between seasons

 

Table 3: Mean value (±SE) of blood serum TPX (umol/L) and TAC (mmol/L) in ewes during the peripartum period at spring (N=7) and summer (N=7).

 

Parameter

Season

Weeks before lambing

Weeks after lambing

-3

-2

-1

1

2

3

TPX

Spring

72.2 ± 6.3 a

77.7 ± 3.7 ab

84.5 ± 4.5 b*

82.8 ± 4.0 b*

84.2 ± 2.8 b

73.4 ± 4.6 a

Summer

81.6 ± 7.7 a

86.6 ± 8.0 ab

97.4 ± 5.1 b

94.01 ± 3.4 b

84.8 ± 4.1 ab

81.7 ± 2.9 a

TAC

Spring

0.83 ± 0.08 a

0.87 ± 0.12 a

0.81 ± 0.13 a*

0.81 ± 0.13 a*

0.94 ± 0.12 b*

0.82 ± 0.13 a

Summer

0.71 ± 0.09 a

0.63 ± 0.08 ab

0.55 ± 0.14 b

0.45 ± 0.11 b

0.50 ± 0.12 b

0.58 ± 0.18 ab

OSI

Spring

8.70 ± 1.2 a

8.93 ± 2.3 ab

10.38 ± 1.9 b*

10.22 ± 2.2 b*

8.93 ± 2.9 ab*

8.95 ± 1.5 a

Summer

11.49 ± 2.1 a

13.75 ± 1.3 ab

17.70 ± 1.7 b

20.89 ± 2.0 b

16.96 ± 1.6 ab

14.09 ± 2.3 a

a, b, c Duncan’s multiple row test: different letters within the same season indicate significantly different results (p

* Indicate significant different values between seasons

 



DISCUSSION

 

The study was designed to evaluate serum oxidant-antioxidant status and degree of oxidative stress index (OSI) in ewes during the peripartum period under tow different ambient temperature. To the best of our knowledge, there is a limited study on determination of the oxidative status and degree of oxidative stress using by TOS and OSI in ruminant (Abuelo et al., 2013; Abdel-Ghani et al., 2016).

 

The significant increase in rectal temperature may attributed to the increased ambient temperature in summer group ewes (Srikandakumar et al., 2003).

 

Heat stressed mammals undergo changes in thermoregulatory mechanisms, which ultimately affect metabolic and hormonal responses as well as alter substrate utilization (Lees et al., 2017). Therefore, a better understanding of how environmentally induced heat stress affects post absorptive metabolism is a main condition to developing improvement strategies targeting the physiological and metabolic ramifications of heat related illnesses (Baumgard and Rhoads, 2013; Sejian et al., 2018).

 

In the current work blood serum concentrations of total cholesterol, triglycerides, HDL and LDL were significantly increased before lambing, and then significantly decreased after lambing.  These results are in accordance with those reported previously by Gradinski-Urbanac et al. (1986) and Nazifi et al. (2002). Gradinski-Urbanac et al. (1986) reported that during pregnancy and at the start of lactation, the serum triglyceride content was high, but fell   during lactation. However, these results contradict those reported by Turk et al. (2015). This increase of cholesterol, triglycerides and HDL during late pregnancy may be linked to the diminished responsiveness of the target tissue to insulin during late pregnancy, predisposes the ewes to increase of cholesterol, triglyceride and lipoproteins concentrations (Schlumbohm et al., 1997). On the other hand, the significant decrease in serum lipids in the post-partum period could be related to the effect of increased lipolysis, which is hormonally regulated, and not an expression of energy deficiency (Holtenius and Hjort 1990).

 

In the current study, season had a significant effect on blood serum lipid profile. Blood serum concentrations of total cholesterol, triglycerides and HDL were significantly decreased in summer when compared with those in spring. Turk et al. (2015) obtained similar results. Belhadj et al. (2016) demonstrated that chronic HS has a direct effect on lipid metabolism and liver enzymatic activities in ruminants. These changes are typical patterns during negative energy balance where dietary and tissue-derived nutrients are allocated to the mammary gland to support milk production (Turk et al., 2008). In addition, these changes could be a consequence of the activity of maternal reproductive glands for steroid hormone synthesis (Turk 2009). This could indicate that animals during summer have mobilized more energy from body reserve to support milk production due to a high environmental temperature exposure (Das et al., 2016).

 

In the last few years, oxidative stress markers have involved in the mechanisms of metabolic disorders, especially important in dairy animals, in which peripartum period imposes great demands on the body's homeostatic mechanisms (Gaál et al., 2006; Ribeiro et al., 2018). Concentration of TAC considers the cumulative action of all the antioxidants, rather than simply the sum of measurable antioxidants and accurately reflects the redox status (Ghiselli et al., 2000).

 

In the current study, TPX concentration was increased at the first week before lambing and continued at a high level during the remaining period in spring and summer when compared with the baseline values. Whereas, concentrations of TAC in spring increased at the second week after lambing. A reverse trend was noticed in summer season, where the values were decreased at the first week before lambing and continued at low level during the first and second weeks after lambing. The increase of oxidants and decreased antioxidants around partum in this study lies with the results obtained previously by Turk et al. (2013; 2015). During the peripartum negative energy balance, a large amount of ROS is being generated in the course of NEFA oxidation in the liver resulting in raised lipoperoxidative processes and lowered antioxidant status (Bionaz et al., 2007; Turk et al., 2008).

 

Heat stress is suggested to be responsible of enhances ROS production and peroxide generation in livestock animals and induces oxidative stress, which can lead to cytotoxicity (Bernabucci et al., 2002; Ganaie et al., 2013; Nizar et al., 2013). In the current study, concentrations of TPX are more enhanced during summer and the values were significantly higher than spring values during the first week before and after lambing. A reverse trend was noticed for TAC where summer values were significantly lower than spring values from the second week before lambing and continued during the remaining period. Our results agree with those previously reported for ruminants by (Ganaie et al., 2013; Nizar et al., 2013; Turk et al., 2015). Di Trana et al. (2006) reported that seasonal rather than nutritional factors have a more pronounced effect on oxidative status markers. This suggested that the summer group had more prolonged negative energy balance and oxidative stress than the spring group (Marai et al., 2007; Belhadj et al., 2016).

 

The presence of OS could either be a consequence of an excessive production of TPX and/or a decrease in the body TAC, and therefore these parameters are strictly interdependent. In the current work, Pearson’s correlation and regression analysis of TPX (as a representative value of the by-product of oxidative stress) with TAC (as a representative value of defense antioxidants) did not reveal significant correlation. The estimation of OSI provides an objective assessment of the relationship between oxidants and antioxidants, not seen by the determination of both components separately. An increase in TPX/ TAC ratio indicates a higher risk for OS because of an increase in ROS production, defensive antioxidant consumption, or both. The biomarker OSI was used in human medicine to evaluate oxidative stress in passive smoker infants and their mothers (Aycicek et al., 2005). It has been used as a new tool to assess redox status in dairy cattle during the transition period (Abuelo et al., 2013). and to investigate the changes in profile of the oxidant and antioxidant indicators throughout pregnancy in goats (Abdel-Ghani et al., 2016). It used also as an oxidative stress marker of redox status in sheep as reference intervals for adult sheep (Oikonomidis et al., 2017). Also, it used for estimation of redox status as a valid tool for providing a detailed picture about the oxidative status of healthy sheep and goats and to show any possible correlation of oxidative stress with daily milk yield or milk components (Cecchini et al., 2018). Here in the present study, the OSI was used to asses the redox status during the peripartum period in sheep reared under the effect of HS under Upper Egypt conditions. When the oxidative stress index is studied in our work, statistical differences between parturition stages were found. Our data suggests that these ewes experienced their maximal oxidative challenge at the first week after parturition. In fact, there are no closed results from other studies to compare our results. However, our data clarify that the maximal oxidative stress occurred at the first week after parturition that was associated with an increase of pro-oxidants rather than reduction of antioxidants during spring. Instead, both the increase in pro-oxidants and the reduction of antioxidants are sharing in the oxidative stress in summer.

 

Can be concluded that, this is a trial study to evaluate the degree of OS in HS ewes during the peripartum period by detection of TPX, TAC levels and OSI value. These ewes experienced their maximal oxidative challenge at the first week postpartum. Further studies to ascertain precisely how the changes in temperature affect the blood biochemistry of animals under different production and reproduction phase.

 

REFERENCES

 

Abdel-Ghani, M.A.; El-Sherry, T.M.; Hayder, M. and Abou-Khalil, N.S. (2016): Profile of peroxidative injury and antioxidant indicators in singleton, twins and multiple bearing goats throughout pregnancy. Asian Pacific Journal of Reproduction, 5(5), 400-405.

Abuelo, A.; Hernandez, J.; Benedito, J.L. and Castillo, C. (2013): Oxidative stress index (OSi) as a new tool to assess redox status in dairy cattle during the transition period. Animal, 7, 1374-1378.

Aycicek, A.; Erel, O. and Kocyigit, A. (2005): Decreased total antioxidant capacity and increased oxidative stress in passive smoker infants and their mothers. Pediatrics International, 47, 635-639.

Baumgard, L.H. and Rhoads, R.P. (2013): Effects of heat stress on postabsorptive metabolism and energetics. Annu. Rev. Anim. Biosci. 1: 311–337.

Belhadj, S.I.; Najar, T.; Ghram, A. and Abdrrabba, M. (2016): Heat stress effects on livestock: molecular, cellular and metabolic aspects, a review. Journal of animal physiology and animal nutrition, 100(3), 401-412.

Belhadj, S.I.; Najar, T.; Ghram, A.; Dabbebi, H.; Ben Mrad, M. and Abedrabbah, M. (2014): Reactive Oxygen Species, Heat Stress and Oxidative-induced Mitochondrial Damage, a Review. International journal of hyperthermia 30, 513–523.

Bernabucci, U.; Ronchi, B.; Lacetera, N. and Nardone, A. (2002): Markers of oxidative status in plasma and erythrocytes of transition dairy cows during hot season. Journal of Dairy Science 85: 2173- 2179.

Bionaz, M.; Trevisi, E.; Calamari, L.; Librandi, F.; Ferrai, A. and Bertoni, G. (2007): Plasma paraoxonase, health, inflammatory conditions, and liver function in transition dairy cows. J Dairy Sci 90, 1740–1750.

Burstein, M.S.H.R.; Scholnick, H.R. and Morfin, R. (1970): Rapid method for the isolation of lipoproteins from human serum by precipitation with polyanions. Journal of lipid research, 11, 583-595.

Cecchini, S.; Piccione, G.; Saoca, C.; Giangrosso, G.; Caputo, A.R. and Fazio, F. (2018): Redox status, and lipid peroxidation and protein oxidation levels in small ruminants. Journal of Animal and Feed Sciences, 27(1), 81-85.

Das, R.; Sailo, L.; Verma, N.; Bharti, P. and Saikia, J. (2016): Impact of heat stress on health and performance of dairy animals: A review. Veterinary world, 9, 260- 268.

Di Trana, A.; Celi, P.; Claps, S.; Fedele, V. and Rubino, R. (2006): The effect of hot season and nutrition on the oxidative status and metabolic profile in dairy goats during mid lactation. Animal Science, 82(5), 717-722.

Erel, O. (2005): A new automated colorimetric method for measuring total oxidant status. Clin Biochem. 38: 1103-1111.

Fassaha, D.M.; Khotijaha, L.; Atabanyb, A.; Mahyardiania, R.R.; Puspadinia, R. and Putraa, A.Y. (2015): Blood malondialdehyde, reproductive, and lactation performances of ewes fed high PUFA rations supplemented with different antioxidant sources. Media Peternakan, 38(1): 48-56.

Fossati, P. and Prencipe, L. (1982): Serum triglycerides determined colorimetrically with an enzyme that produces hydrogen peroxide. Clinical chemistry, 28(10), 2077-2080.

Friedewald, W.T.; Levy, R.I. and Fredrickson, D.S. (1972): Estimation of the concentration of low-density lipoprotein cholesterol in plasma, without use of the preparative ultracentrifuge. Clinical Chemistry 18: 499–502.

Gaál, T.; Ribiczeyné-Szabó, P.; Stadler, K.; Jakus, J.; Reiczigel, J.; Kövér, P.; Mézes, M. and Sümeghy, L. (2006): Free radicals, lipid peroxidation and the antioxidant system in the blood of cows and newborn calves around calving. Comp. Biochem. Physiol. B. 143: 391–396.

Ganaie, A.H.; Ghasura, R.S.; Mir, N.A.; Bumla, N.A.; Sankar, G. and Wani, S.A. (2013): Biochemical and physiological changes during thermal stress in bovines: a review. Iranian Journal of Applied Animal Science, 3, 423-430.

Ghiselli, A.; Serafini, M.; Natella, F. and Scaccini, C. (2000): Total antioxidant capacity as a tool to assess redox status: critical view and experimental data. Free Radical Biology and Medicine, 29, 1106-1114.

Gradinski-Urbanac, B.; Mitin, V.; Mikulec, K. and Karadjole, I. (1986): Triglycerides and phospholipid values in sheep serum in the course of a year. Veterinary Archiv 55, 29-31.

Gutteridge, J.M. and Halliwell, B. (2018): Mini-Review: Oxidative stress, redox stress or redox success?. Biochemical and biophysical research communications.

Halliwell, B. and Gutteridge, J.M. (2017): Free radicals in biology and medicine. Acta Crystallogr., 73, 384-385.

Holtenius, P. and Hjort, M. (1990): Studies on the pathogenesis of fatty liver in cows. Bovine Practice 25, 91-94.

Ingvartsen, K.L. and Andersen, J.B. (2000): Integration of metabolism and intake regulation: a review focusing on periparturient animals. J Dairy Sci 83: 1573–1597.

Johnson, J.S.; Abuajamieh, M.; Fernandez, M.S.; Seibert, J.T.; Stoakes, S.K.; Nteeba, J. and Baumgard, L. (2015): Thermal Stress Alters Postabsorptive Metabolism During Pre- and Postnatal Development. In: Sejian V., Gaughan J., Baumgard L., Prasad C. (Eds) Climate Change Impact on Livestock: Adaptation and Mitigation. springer, New Delhi. Pp 61-79.

Koracevic, D.; Koracevic, G.; Djordjevic, V.; Andrejevic, S. and Cosic, V. (2001): Method for the measurement of antioxidant activity in human fluids. J Clin Pathol. 2001 May; 54(5):356-61.

Lees, A.M.; Lees, J.C.; Sejian, V. and Gaughan, J. (2017): Management Strategies to Reduce Heat Stress in Sheep. In Sheep Production Adapting to Climate Change (pp. 349-370). springer, Singapore.

Marai, I.F.M.; El-Darawany, A.A.; Fadiel, A. and Abdel-Hafez, M.A.M. (2007): Physiological traits as affected by heat stress in sheep—a review. Small ruminant research, 71(1-3), 1-12.

McKinley, M.; Trevaks, D.; Weissenborn, F. and McAllen, R. (2017): Interaction between thermoregulation and osmoregulation in domestic animals. Revista Brasileira de Zootecnia, 46, 783-790.

Mutinati, M., M. Piccinno, M. Roncetti, D. Campanile, A. Rizzo, and R.L. Sciorsci (2013): Oxidative stress during pregnancy in the sheep. Review article. Reprod. Dom. Anim., 48: 353–206 357.

Nazifi, S.; Saeb, M. and Ghavami, S.M. (2002): Serum lipid profile in iranian fat-tailed sheep in late pregnancy, at parturition and during the post-parturition period. Journal of Veterinary Medicine Series A, 49, 9-12.

Nizar, A.N.; Mudasir, S. and Hina, A.W. (2013): Oxidative stress - Threat to animal health and production. International Journal of Livestock Research 3, 76–83.

Oikonomidis, I.L.; Kiosis, E.A.; Brozos, C.N. and Kritsepi-Konstantinou, M.G. (2017): Reference intervals for serum reactive oxygen metabolites, biological antioxidant potential, and oxidative stress index in adult rams. American journal of veterinary research, 78, 274-278.

Pandey, N.; Kataria, N.; Kumar, Kataria. A.; Joshi, A.; Narayan Sankhala, L.; Asopa, S. and Pachaury, R. (2012): Extreme ambiances vis-a-vis endogenous antioxidants of Marwari goat from arid tracts in India. ELBA Bioflux 4, 29–33.

Ribeiro, M.N.; Ribeiro, N.L.; Bozzi, R. and Costa, R.G. (2018): Physiological and biochemical blood variables of goats subjected to heat stress–a review. Journal of Applied Animal Research, 46, 1036-1041.

Richmond, W. (1973): Preparation and properties of a cholesterol oxidase from Nocardia sp. and its application to the enzymatic assay of total cholesterol in serum. Clinical chemistry, 19, 1350-1356.

Schlumbohm, C.;  Sporleder, H.P.; Gurtler, H. and  Harmeyer, J. (1997): The influence of insulin on metabolism of glucose, free fatty acids and glycerol in normo- and hypocalcaemic ewes during different reproductive states. Deutsche Tierarzl. Wochens. 104, 359–365.

Sejian, V.; Bhatta, R.; Gaughan, J.B.; Dunshea, F.R. and Lacetera, N. (2018): Adaptation of animals to heat stress animal, 1-14.  

Srikandakumar, A.; Johnson, E.H. and Mahgoub, O. (2003): Effect of heat stress on respiratory rate, rectal temperature and blood chemistry in Omani and Australian Merino sheep. Small Ruminant Research 49, 193-198.

Silanikove, N. (2000): Effects of heat stress on the welfare of extensively managed domestic ruminants. Livest Prod Sci. 67: 1–18.

SPSS (2002): ANOVA in Sample Power Statistics, SPSS, Syntax Reference Guide for SPSS Base. SPSS Inc., 233 South Wacker Drive, Chicago, IL. pp 111-119.

Turk, R. (2009): The role of HDL-associated enzymes in bovine reproduction. In: Pagano SI, Strait BN (eds), HDL and LDL Cholesterol: Physiology and Clinical Significance. Nova Science Publishers nc., New York, pp. 1–17.

Turk, R.; Jureti,_CD.; Gere,_SD.; Svetina, A.; Turk, N. and Flegar-Me_stri_cZ. (2008): Influence of oxidative stress and metabolic adaptation on PON1 activity and MDA concentration in transition dairy cows. Anim Reprod Sci 108, 98–106.

Turk, R.; Podpe, Can, O.; Mrkun, J.; Kosec, M.; Flegar-Me_stri, CZ.; Perkov, S.; Stari, CJ.; Robi, CM.; Beli, CM. and Zrim_sek. P. (2013): Lipid mobilisation and oxidative stress as metabolic adaptation processes in dairy heifers during transition period. Anim Reprod Sci 141, 109–115.

Turk, R.; Podpečan, O.; Mrkun, J.; FlegarMeštrić, Z.; Perkov, S. and Zrimšek, P. (2015): The effect of seasonal thermal stress on lipid mobilisation, antioxidant status and reproductive performance in dairy cows. Reproduction in domestic animals. 50,      595-603.

 

 

 

 

 

تأثير درجة حرارة الجو على التغيرات الدموية لمؤشر الإجهاد التأکسدي الکلي  وصورة الدهون فى النعاج

حول الولادة

 

غاده عبد العظيم محمد، هيام محمد المصطفى منزلي

 

E-mail: dr_kada2012@yahoo.com      Assiut University web-site: www.aun.edu.eg

 

استخدم مؤشر الإجهاد التأکسدي (OSI) حديثا کأداة لتقديم صورة واضحة عن حالة الأکسدة والاختزال التأکسدي . تم الدراسة على 14 نعجة أوسيمي متعددة الولادات (1,5-2 سنة ، 35-40 کجم) في محطة البحوث الزراعية بأسيوط خلال موسم الربيع (مجموعة ضابطة (N=7  وخلال الصيف (مجموعة الاجهاد الحراري(N=7  . أخذت عينات دم من النعاج أسبوعيًا على مدار الأسابيع الثلاثة الأخيرة قبل الولادة وأسبوعيًا خلال الأسابيع الثلاثة الأولى بعد الولادة لفحص دهون المصل والمؤشرات الحيوية للإجهاد التأکسدي. أظهرت النتائج زيادة الکوليسترول  الکلى والدهون الثلاثية والبروتينات الدهنية عالية ومنخفضة الکثافة (P <0.05) قبل الولادة ثم نقصت بعد الولادة(p <0.05). کان الکوليسترول والدهون الثلاثية والبروتينات الدهنية عالية الکثافة (HDL) أقل في الصيف مقارنة بالربيع(p <0.05). في فصلي الربيع والصيف ازداد إجمالي البيروکسيد الکلى (TPX) في الأسبوع الأول قبل وبعد الولادة(p <0.05)  بالاضافة الى ان قيم الصيف کانت أعلى من قيم الربيع(p<0.05). في الربيع ازدادت السعة الکلية لمضادات الأکسدة (TAC)  في الأسبوع الثاني بعد الولادة (p<0.05)  ، في حين لوحظ اتجاه عکسي في فصل الصيف حيث کانت قيم TAC الصيفية أقل من قيم الربيع(P <0.05). معامل بيرسون للارتباط والانحدار بين TPX و TACلم يظهر اي دلالات معنوية . بينما ارتفعت قيم مؤشر الإجهاد التأکسدي  (OSI = TPX  / TAC) x100تدريجيًا (p <0.05) في الصيف ووصلت إلى القيمة القصوى في الأسبوع الأول بعد الولادة ، ثم انخفضت بشکل مطرد في الأسبوع الثالث بعد الولادة . کانت قيم  TPX الصيفية أعلى (p<0.05)  من قيم الربيع .واخيرا , هذه الدراسة هي الأولى لتقييم الاجهاد التأکسدي في النعاج المجهدة حراريا خلال فترة الحمل عن طريق الکشف عن قيم TPX و TAC و OSI . کما أوضحت البيانات أن اقصى إجهاد التأکسدي حدث في الأسبوع الأول بعد الولادة والذي کان مرتبطا بزيادة البيروکسيد عن نقص مضادات الأکسدة خلال الربيع. ولکن، فإن کلا من زيادة البيروکسيد ونقص مضادات الأکسدة تقاسمت السبب في الإجهاد التأکسدي في الصيف.

 

 

 

 

 

 

 

 

Abdel-Ghani, M.A.; El-Sherry, T.M.; Hayder, M. and Abou-Khalil, N.S. (2016): Profile of peroxidative injury and antioxidant indicators in singleton, twins and multiple bearing goats throughout pregnancy. Asian Pacific Journal of Reproduction, 5(5), 400-405.
Abuelo, A.; Hernandez, J.; Benedito, J.L. and Castillo, C. (2013): Oxidative stress index (OSi) as a new tool to assess redox status in dairy cattle during the transition period. Animal, 7, 1374-1378.
Aycicek, A.; Erel, O. and Kocyigit, A. (2005): Decreased total antioxidant capacity and increased oxidative stress in passive smoker infants and their mothers. Pediatrics International, 47, 635-639.
Baumgard, L.H. and Rhoads, R.P. (2013): Effects of heat stress on postabsorptive metabolism and energetics. Annu. Rev. Anim. Biosci. 1: 311–337.
Belhadj, S.I.; Najar, T.; Ghram, A. and Abdrrabba, M. (2016): Heat stress effects on livestock: molecular, cellular and metabolic aspects, a review. Journal of animal physiology and animal nutrition, 100(3), 401-412.
Belhadj, S.I.; Najar, T.; Ghram, A.; Dabbebi, H.; Ben Mrad, M. and Abedrabbah, M. (2014): Reactive Oxygen Species, Heat Stress and Oxidative-induced Mitochondrial Damage, a Review. International journal of hyperthermia 30, 513–523.
Bernabucci, U.; Ronchi, B.; Lacetera, N. and Nardone, A. (2002): Markers of oxidative status in plasma and erythrocytes of transition dairy cows during hot season. Journal of Dairy Science 85: 2173- 2179.
Bionaz, M.; Trevisi, E.; Calamari, L.; Librandi, F.; Ferrai, A. and Bertoni, G. (2007): Plasma paraoxonase, health, inflammatory conditions, and liver function in transition dairy cows. J Dairy Sci 90, 1740–1750.
Burstein, M.S.H.R.; Scholnick, H.R. and Morfin, R. (1970): Rapid method for the isolation of lipoproteins from human serum by precipitation with polyanions. Journal of lipid research, 11, 583-595.
Cecchini, S.; Piccione, G.; Saoca, C.; Giangrosso, G.; Caputo, A.R. and Fazio, F. (2018): Redox status, and lipid peroxidation and protein oxidation levels in small ruminants. Journal of Animal and Feed Sciences, 27(1), 81-85.
Das, R.; Sailo, L.; Verma, N.; Bharti, P. and Saikia, J. (2016): Impact of heat stress on health and performance of dairy animals: A review. Veterinary world, 9, 260- 268.
Di Trana, A.; Celi, P.; Claps, S.; Fedele, V. and Rubino, R. (2006): The effect of hot season and nutrition on the oxidative status and metabolic profile in dairy goats during mid lactation. Animal Science, 82(5), 717-722.
Erel, O. (2005): A new automated colorimetric method for measuring total oxidant status. Clin Biochem. 38: 1103-1111.
Fassaha, D.M.; Khotijaha, L.; Atabanyb, A.; Mahyardiania, R.R.; Puspadinia, R. and Putraa, A.Y. (2015): Blood malondialdehyde, reproductive, and lactation performances of ewes fed high PUFA rations supplemented with different antioxidant sources. Media Peternakan, 38(1): 48-56.
Fossati, P. and Prencipe, L. (1982): Serum triglycerides determined colorimetrically with an enzyme that produces hydrogen peroxide. Clinical chemistry, 28(10), 2077-2080.
Friedewald, W.T.; Levy, R.I. and Fredrickson, D.S. (1972): Estimation of the concentration of low-density lipoprotein cholesterol in plasma, without use of the preparative ultracentrifuge. Clinical Chemistry 18: 499–502.
Gaál, T.; Ribiczeyné-Szabó, P.; Stadler, K.; Jakus, J.; Reiczigel, J.; Kövér, P.; Mézes, M. and Sümeghy, L. (2006): Free radicals, lipid peroxidation and the antioxidant system in the blood of cows and newborn calves around calving. Comp. Biochem. Physiol. B. 143: 391–396.
Ganaie, A.H.; Ghasura, R.S.; Mir, N.A.; Bumla, N.A.; Sankar, G. and Wani, S.A. (2013): Biochemical and physiological changes during thermal stress in bovines: a review. Iranian Journal of Applied Animal Science, 3, 423-430.
Ghiselli, A.; Serafini, M.; Natella, F. and Scaccini, C. (2000): Total antioxidant capacity as a tool to assess redox status: critical view and experimental data. Free Radical Biology and Medicine, 29, 1106-1114.
Gradinski-Urbanac, B.; Mitin, V.; Mikulec, K. and Karadjole, I. (1986): Triglycerides and phospholipid values in sheep serum in the course of a year. Veterinary Archiv 55, 29-31.
Gutteridge, J.M. and Halliwell, B. (2018): Mini-Review: Oxidative stress, redox stress or redox success?. Biochemical and biophysical research communications.
Halliwell, B. and Gutteridge, J.M. (2017): Free radicals in biology and medicine. Acta Crystallogr., 73, 384-385.
Holtenius, P. and Hjort, M. (1990): Studies on the pathogenesis of fatty liver in cows. Bovine Practice 25, 91-94.
Ingvartsen, K.L. and Andersen, J.B. (2000): Integration of metabolism and intake regulation: a review focusing on periparturient animals. J Dairy Sci 83: 1573–1597.
Johnson, J.S.; Abuajamieh, M.; Fernandez, M.S.; Seibert, J.T.; Stoakes, S.K.; Nteeba, J. and Baumgard, L. (2015): Thermal Stress Alters Postabsorptive Metabolism During Pre- and Postnatal Development. In: Sejian V., Gaughan J., Baumgard L., Prasad C. (Eds) Climate Change Impact on Livestock: Adaptation and Mitigation. springer, New Delhi. Pp 61-79.
Koracevic, D.; Koracevic, G.; Djordjevic, V.; Andrejevic, S. and Cosic, V. (2001): Method for the measurement of antioxidant activity in human fluids. J Clin Pathol. 2001 May; 54(5):356-61.
Lees, A.M.; Lees, J.C.; Sejian, V. and Gaughan, J. (2017): Management Strategies to Reduce Heat Stress in Sheep. In Sheep Production Adapting to Climate Change (pp. 349-370). springer, Singapore.
Marai, I.F.M.; El-Darawany, A.A.; Fadiel, A. and Abdel-Hafez, M.A.M. (2007): Physiological traits as affected by heat stress in sheep—a review. Small ruminant research, 71(1-3), 1-12.
McKinley, M.; Trevaks, D.; Weissenborn, F. and McAllen, R. (2017): Interaction between thermoregulation and osmoregulation in domestic animals. Revista Brasileira de Zootecnia, 46, 783-790.
Mutinati, M., M. Piccinno, M. Roncetti, D. Campanile, A. Rizzo, and R.L. Sciorsci (2013): Oxidative stress during pregnancy in the sheep. Review article. Reprod. Dom. Anim., 48: 353–206 357.
Nazifi, S.; Saeb, M. and Ghavami, S.M. (2002): Serum lipid profile in iranian fat-tailed sheep in late pregnancy, at parturition and during the post-parturition period. Journal of Veterinary Medicine Series A, 49, 9-12.
Nizar, A.N.; Mudasir, S. and Hina, A.W. (2013): Oxidative stress - Threat to animal health and production. International Journal of Livestock Research 3, 76–83.
Oikonomidis, I.L.; Kiosis, E.A.; Brozos, C.N. and Kritsepi-Konstantinou, M.G. (2017): Reference intervals for serum reactive oxygen metabolites, biological antioxidant potential, and oxidative stress index in adult rams. American journal of veterinary research, 78, 274-278.
Pandey, N.; Kataria, N.; Kumar, Kataria. A.; Joshi, A.; Narayan Sankhala, L.; Asopa, S. and Pachaury, R. (2012): Extreme ambiances vis-a-vis endogenous antioxidants of Marwari goat from arid tracts in India. ELBA Bioflux 4, 29–33.
Ribeiro, M.N.; Ribeiro, N.L.; Bozzi, R. and Costa, R.G. (2018): Physiological and biochemical blood variables of goats subjected to heat stress–a review. Journal of Applied Animal Research, 46, 1036-1041.
Richmond, W. (1973): Preparation and properties of a cholesterol oxidase from Nocardia sp. and its application to the enzymatic assay of total cholesterol in serum. Clinical chemistry, 19, 1350-1356.
Schlumbohm, C.;  Sporleder, H.P.; Gurtler, H. and  Harmeyer, J. (1997): The influence of insulin on metabolism of glucose, free fatty acids and glycerol in normo- and hypocalcaemic ewes during different reproductive states. Deutsche Tierarzl. Wochens. 104, 359–365.
Sejian, V.; Bhatta, R.; Gaughan, J.B.; Dunshea, F.R. and Lacetera, N. (2018): Adaptation of animals to heat stress animal, 1-14.  
Srikandakumar, A.; Johnson, E.H. and Mahgoub, O. (2003): Effect of heat stress on respiratory rate, rectal temperature and blood chemistry in Omani and Australian Merino sheep. Small Ruminant Research 49, 193-198.
Silanikove, N. (2000): Effects of heat stress on the welfare of extensively managed domestic ruminants. Livest Prod Sci. 67: 1–18.
SPSS (2002): ANOVA in Sample Power Statistics, SPSS, Syntax Reference Guide for SPSS Base. SPSS Inc., 233 South Wacker Drive, Chicago, IL. pp 111-119.
Turk, R. (2009): The role of HDL-associated enzymes in bovine reproduction. In: Pagano SI, Strait BN (eds), HDL and LDL Cholesterol: Physiology and Clinical Significance. Nova Science Publishers nc., New York, pp. 1–17.
Turk, R.; Jureti,_CD.; Gere,_SD.; Svetina, A.; Turk, N. and Flegar-Me_stri_cZ. (2008): Influence of oxidative stress and metabolic adaptation on PON1 activity and MDA concentration in transition dairy cows. Anim Reprod Sci 108, 98–106.
Turk, R.; Podpe, Can, O.; Mrkun, J.; Kosec, M.; Flegar-Me_stri, CZ.; Perkov, S.; Stari, CJ.; Robi, CM.; Beli, CM. and Zrim_sek. P. (2013): Lipid mobilisation and oxidative stress as metabolic adaptation processes in dairy heifers during transition period. Anim Reprod Sci 141, 109–115.
Turk, R.; Podpečan, O.; Mrkun, J.; FlegarMeštrić, Z.; Perkov, S. and Zrimšek, P. (2015): The effect of seasonal thermal stress on lipid mobilisation, antioxidant status and reproductive performance in dairy cows. Reproduction in domestic animals. 50,      595-603.