International Journal of Research and Reports in Hematology

Haematological Alterations in Heat-Stressed Male Wistar Rats

Onyinye Ukamaka Umeh

Department of Human Physiology, Faculty of Basic Medical Sciences, College of Health Sciences, University of Port Harcourt, Port Harcourt, Nigeria.

Bruno Chukwuemeka Chinko *

Department of Human Physiology, Faculty of Basic Medical Sciences, College of Health Sciences, University of Port Harcourt, Port Harcourt, Nigeria.

*Author to whom correspondence should be addressed.

---

Abstract

Background: Heat stress (HS) occurs due to global rising temperatures and the exposure of certain industrial workers to hot ambient temperatures. Physiological adaptability to heat stress involves long-term hemorheological modifications.

Objectives: The present study evaluated the effect of heat stress on haematological profile using heat-stressed Wistar rat models.

Materials and Methods: The study involved using twenty (20) male apparently healthy Wistar rats, with a weight range of 200-250g and an age range of 12-16 weeks. Before the study, the rats were acclimated for two weeks under standard animal husbandry conditions. To simulate heat stress (HS), a heating chamber was utilized and maintained at a temperature of 38±1˚C. The animals were randomly grouped into five (5), comprising five (5) animals per group. Group 1 served as the control and was not exposed to HS, while Groups 2, 3 and 4 were exposed to HS inside the heating chamber, regulated at  38±1˚C for 2, 4 and 8 hours respectively for thirty 30 days. Animals were anaesthetized by cervical dislocation and blood was collected by cardiac puncture for haematological analysis: packed cell volume (PCV), haemoglobin concentration (Hb),  red blood cell (RBC), white blood cell (WBC), MID cells percentage (MID), lymphocytes, neutrophil and platelet counts were determined using a haematology auto-analyzer. Other haematological indices: mean corpuscular volume (MCV), mean corpuscular haemoglobin (MCH), mean corpuscular haemoglobin concentration (MCHC), neutrophil-lymphocyte ratio (NLR), platelet-lymphocyte ratio (PLR), total lymphocyte count (TLC), plateletcrit (PCT), mean platelet volume (MPV), platelet distribution width (PDW) and platelet large ratio (PCLR) were determined in line with standard formulae.

Results: Data from the study indicated a significantly raised PCV, RBC, Hb, NLR and PLR among the heat-exposed groups compared to the control (p<0.05). Also, mean values of WBC, TLC, lymphocytes and MPV significantly decreased compared to the control (p<0.05).

Conclusion: Long-term hemorheological changes are involved in the physiological adaptation to heat stress. According to the information from the current study, it appears that HS caused a rise in the PVC, Hb RBC, NLR, and PLR levels and a decrease in WBC, TLC, lymphocytes, and MPV. The data points to HS as a potential cause of increased blood viscosity, inflammation, and tissue damage, as well as immune system suppression and disruption of platelet synthesis and activation.

Keywords: Heat stress, haematology, red blood cell, white blood cell, mean platelet volume

---

---

---

References

Soeder DJ, Soeder DJ. Fossil fuels and climate change. Fracking and the Environment: A scientific assessment of the environmental risks from hydraulic fracturing and fossil fuels. 2021:155-85.

Letcher TM. Why do we have global warming? Managing Global Warming: Elsevier. 2019:3-15.

Amoo LM, Fagbenle RL. Climate change in developing nations of the world. Applications of Heat, Mass and Fluid Boundary Layers: Elsevier. 2020:437-71.

Dincer I. Renewable energy and sustainable development: A crucial review. Renewable and Sustainable Energy Reviews. 2000;4(2):157-75.

Spector JT, Masuda YJ, Wolff NH, Calkins M, Seixas N. Heat exposure and occupational injuries: review of the literature and implications. Current environmental health reports. 2019;6:286-96.

Ioannou LG, Foster J, Morris NB, Piil JF, Havenith G, Mekjavic IB, et al. Occupational heat strain in outdoor workers: A comprehensive review and meta-analysis. Temperature. 2022;9(1):67-102.

Kovats RS, Hajat S. Heat stress and public health: A critical review. Annu. Rev. Public Health. 2008;29:41-55.

Addo-Bediako A, Chown SL, Gaston KJ. Thermal tolerance, climatic variability and latitude. Proceedings of the Royal Society of London. Series B: Biological Sciences. 2000;267(1445):739-45.

Collier RJ, Baumgard LH, Zimbelman RB, Xiao Y. Heat stress: Physiology of acclimation and adaptation. Animal Frontiers. 2019;9(1):12-9.

Cheung SS, McLellan TM, Tenaglia S. The thermophysiology of uncompensable heat stress. Sports Medicine. 2000;29(5):329-59.

Gonzalez-Rivas PA, Chauhan SS, Ha M, Fegan N, Dunshea FR, Warner RD. Effects of heat stress on animal physiology, metabolism, and meat quality: A review. Meat Science. 2020;162:108025.

Rashamol VP, Sejian V, Bagath M, Krishnan G, Archana PR, Bhatta R. Physiological adaptability of livestock to heat stress: An updated review. Journal of Animal Behaviour and Biometeorology. 2020;6(3):62-71.

Chinko BC, Umeh OU. Alterations in lipid profile and oxidative stress markers following heat stress on wistar rats: Ameliorating role of vitamin C. Biomedical Sciences. 2023;9(1):12-7.

Nakamura K, Morrison SF. A thermosensory pathway that controls body temperature. Nature Neuroscience. 2008;11(1):62-71.

Seebacher F, Franklin CE. Physiological mechanisms of thermoregulation in reptiles: A review. Journal of Comparative Physiology B. 2005;175:533-41.

Mortola JP, Frappell PB. Ventilatory responses to changes in temperature in mammals and other vertebrates. Annual Review of Physiology. 2000;62(1):847-74.

Sarangi S. Adaptability of goats to heat stress: A review. The Pharma Innovation Journal. 2018;7(4):1114-26.

Caspani M, Savioli M, Crotti S, Bruzzone P, Gattinoni L. Heat stress: Characteristics, pathophysiology and avoidable mistakes. Minerva Anestesiologica. 2004;70(7-8): 617-24.

Roti Roti JL. Cellular responses to hyperthermia (40–46 C): Cell killing and molecular events. International Journal of Hyperthermia. 2008;24(1):3-15.

Halliwell B, Cross CE. Oxygen-derived species: Their relation to human disease and environmental stress. Environmental Health Perspectives. 1994;102(suppl 10): 5-12.

Storey KB. Oxidative stress: Animal adaptations in nature. Brazilian Journal of Medical and Biological Research. 1996;29:1715-33.

Lin H, Du R, Zhang Z. Peroxide status in tissues of heat-stressed broilers. Asian-Australasian Journal of Animal Sciences. 2000;13(10):1373-6.

Yanay O, Gilad E. Heat injury. Pediatric critical care: Elsevier; 2011:1472-6.

Mantha L, Palacios E, Deshaies Y. Modulation of triglyceride metabolism by glucocorticoids in diet-induced obesity. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology. 1999;277(2):R455-R64.

Wen X, Wu W, Fang W, Tang S, Xin H, Xie J, et al. Effects of long-term heat exposure on cholesterol metabolism and immune responses in growing pigs. Livestock Science. 2019;230:103857.

Habeeb A, El-Tarabany A, Gad A, Atta M. Negative effects of heat stress on physiological and immunity responses of farm animals. Change. 2018;16(2.0):0-2.

Bain BJ, Bates I, Laffan MA. Dacie and lewis practical haematology e-book: Elsevier Health Sciences; 2016.

Rozenberg G. Microscopic haematology: A practical guide for the laboratory. Elsevier Australia; 2011.

Faria SS, Fernandes Jr PC, Silva MJB, Lima VC, Fontes W, Freitas-Junior R, et al. The neutrophil-to-lymphocyte ratio: A narrative review. Ecancermedicalscience. 2016;10.

Balta S, Ozturk C. The platelet-lymphocyte ratio: A simple, inexpensive and rapid prognostic marker for cardiovascular events. Platelets. 2015;26(7):680-1.

Kwon H-C, Kim SH, Oh SY, Lee S, Lee JH, Choi H-J, et al. Clinical significance of preoperative neutrophil-lymphocyte versus platelet-lymphocyte ratio in patients with operable colorectal cancer. Biomarkers. 2012;17(3):216-22.

Chinko BC, Pughikumo DT. Haematological and hepatorenal alterations induced by potash (akanwu) on male wistar rats. International Blood Research & Reviews. 2023;14(1):38-46.

Ocheja OB, Ayo JO, Aluwong T, Minka NS. Ameliorative effects of L-glutamine on haematological parameters in heat-stressed red sokoto goats. Journal of Thermal Biology. 2020;90:102571.

Okoruwa MI. Effect of heat stress on thermoregulatory, live bodyweight and physiological responses of dwarf goats in southern Nigeria. European Scientific Journal. 2014;10(27):255-64.

Al-Dawood A. Towards heat stress management in small ruminants-a review. Annals of Animal Science. 2017;17(1):59-88.

Sawka MN, Gonzalez RR, Young AJ, Muza SR, Pandolf KB, Latzka WA, et al. Polycythemia and hydration: Effects on thermoregulation and blood volume during exercise-heat stress. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology. 1988;255(3): R456-R63.

Stewart IB, McKenzie DC. The human spleen during physiological stress. Sports Medicine. 2002;32:361-9.

Rana MS, Hashem MA, Sakib MN, Kumar A. Effect of heat stress on blood parameters in indigenous sheep. Journal of the Bangladesh Agricultural University. 2014;12(1):91-4.

Alam MM, Hashem MA, Rahman MM, Hossain MM, Haque MR, Sobhan Z, et al. Effect of heat stress on behavior, physiological and blood parameters of goat. Progressive Agriculture. 2011;22(1-2):37-45.

Odo RI, Onoja SO, Osuagwu CO. Impact of heat stress on blood and serum biochemistry parameters in rats. Notulae Scientia Biologicae. 2019;11(3):347.

Srikandakumar A, Johnson EH, Mahgoub O. Effect of heat stress on respiratory rate, rectal temperature and blood chemistry in Omani and Australian Merino sheep. Small Ruminant Research. 2003;49(2):193-8.

Sivakumar AVN, Singh G, Varshney VP. Antioxidants supplementation on acid base balance during heat stress in goats. Asian-Australasian Journal of Animal Sciences. 2010;23(11):1462-8.

Chinko BC, Amah-Tariah FS, Ekenna IC. Evaluation of the effects of calabash chalk on the haematological profile of Wistar rats. Notulae Scientia Biologicae. 2022;14(3):11281.

Inbaraj S, Sejian V, Bagath M, Bhatta R. Impact of heat stress on immune responses of livestock: A review. Pertanika Journal of Tropical Agricultural Science. 2016;39(4).

Zahorec R. Neutrophil-to-lymphocyte ratio, past, present and future perspectives. Bratislavske Lekarske Listy. 2021;122(7):474-88.

Song M, Graubard BI, Rabkin CS, Engels EA. Neutrophil-to-lymphocyte ratio and mortality in the United States general population. Scientific Reports. 2021;11(1): 464.

Buonacera A, Stancanelli B, Colaci M, Malatino L. Neutrophil to lymphocyte ratio: An emerging marker of the relationships between the immune system and diseases. International Journal of Molecular Sciences. 2022;23(7): 3636.

Malyar RM, Li H, Liu D, Abdulrahim Y, Farid RA, Gan F, et al. Selenium/Zinc-Enriched probiotics improve serum enzyme activity, antioxidant ability, inflammatory factors and related gene expression of wistar rats inflated under heat stress. Life Sciences. 2020;248: 117464.

Gunaldi M, Goksu S, Erdem D, Gunduz S, Okuturlar Y, Tiken E, et al. Prognostic impact of platelet/lymphocyte and neutrophil/lymphocyte ratios in patients with gastric cancer: A multicenter study. International Journal of Clinical and Experimental Medicine. 2015; 8(4):5937.

Sloop GD, De Mast Q, Pop G, Weidman JJ, Cyr JAS. The role of blood viscosity in infectious diseases. Cureus. 2020;12(2).

Yuri Gasparyan A, Ayvazyan L, Mikhailidis DP, Kitas GD. Mean platelet volume: a link between thrombosis and inflammation? Current Pharmaceutical Design. 2011;17(1):47-58.

Park Y, Schoene N, Harris W. Mean platelet volume as an indicator of platelet activation: Methodological issues. Platelets. 2002;13(5-6):301-6.

Schmoeller D, Picarelli MM, Paz Munhoz T, Poli de Figueiredo CE, Staub HL. Mean platelet volume and immature platelet fraction in autoimmune disorders. Frontiers in Medicine. 2017;4:146.

Lippi G, Franchini M. Platelets and immunity: the interplay of mean platelet volume in health and disease. Taylor & Francis. 2015:555-7.