Morphofunctional study on the effects of passive smoking in kidneys of rats

Moraes, Carlos Alberto de; Breda-Stella, Mercia; Carvalho, Cesar Alexandre Fabrega

doi:10.31744/einstein_journal/2021AO6000

ABSTRACT

Objective

To analyze whether passive inhalation of cigarette smoke causes morphological, structural, and functional changes in kidneys of rats.

Methods

Wistar rats, aged eight weeks, weighing on average 260g, were divided into Control Group and Smoking Group. Each group was subdivided into four groups of ten animals for morphofunctional analysis, in a period of seven and 28 days. The Smoking Group was exposed to smoke of 40 cigarettes per day, at certain times and in automated equipment for cigarette burning, called smoking machine (SM-MC-01). After the exposure period, urine and blood samples were collected for the functional analyses, and the kidneys were dissected and submitted to histological procedures for morphoquantitative analyses.

Results

After exposure of animals of the Smoking Group, the following were observed: lower weight gain; lower water and feed intake; decreased renal weight, diameter, and volume; reduction in cortical thickness and glomerular volume density; decrease in glomerular and capsular diameter; increase in mesangial density; decreased urine volume; increased levels of glucose, serum creatinine and microalbuminuria; decreased urinary creatinine levels and creatinine clearance rate.

Conclusion

Passive smoking negatively influences renal morphology and glomerular filtration rate, with effects similar to those described in the literature regarding active smoking.

Tobacco smoke pollution; Kidney cortex; Kidney glomerulus; Mesangial cells; Diabetic nephropathies; Glomerular filtration rate; Rats, Wistar

RESUMO

Objetivo

Analisar se a inalação passiva da fumaça do cigarro proporciona alterações morfológicas, estruturais e funcionais nos rins de ratos.

Métodos

Ratos Wistar, com oito semanas de idade, pesando, em média, 260g, foram divididos em Grupo Controle e Grupo Tabagista. Cada grupo foi subdividido em quatro grupos de dez animais para análise morfofuncional, em um período de sete e 28 dias. O Grupo Tabagista foi exposto à fumaça de 40 cigarros por dia, em horários determinados e equipamento automatizado de queima de cigarros, denominado smoking machine (SM-MC-01). Após o período de exposição, foram coletadas amostras de urina e sangue para as análises funcionais, e os rins foram dissecados e submetidos a procedimentos histológicos para análises morfoquantitativas.

Resultados

Após a exposição dos animais do Grupo Tabagista, observou-se menor ganho de peso; menor consumo de água e ração; menor peso, diâmetro e volume renal; redução em espessura cortical e densidade de volume glomerular; diminuição no diâmetro glomerular e capsular; aumento na densidade mesangial; volume urinário diminuído; níveis aumentados de glicose, creatinina sérica e microalbuminúria; níveis reduzidos de creatinina urinária e redução da taxa de depuração da creatinina.

Conclusão

O tabagismo passivo influencia negativamente na morfologia renal e na taxa de filtração glomerular, com efeitos semelhantes aos descritos na literatura em relação ao tabagismo ativo.

Poluição por fumaça de tabaco; Córtex renal; Glomérulos renais; Células mesangiais; Nefropatias diabéticas; Taxa de filtração glomerular; Ratos Wistar

INTRODUCTION

According to the World Health Organization (WHO), smoking is the leading cause of preventable death in the world, affecting 8 million individuals per year, and approximately 1.2 million of these deaths result from individuals exposed to secondhand smoke.(¹1. Brasil. Ministério da Saúde. Instituto Nacional de Câncer (INCA). Tabagismo. Rio de Janeiro: INCA; 2020 [citado 2020 Nov 13]. Disponível em: https://www.inca.gov.br/tabagismo
https://www.inca.gov.br/tabagismo... ) Cigarettes are composed of thousands of chemical components, recently estimated to be 5,600. Among them, 158 have toxicological properties capable of polluting the environment through smoke,(²2. Talhout R, Schulz T, Florek E, van Benthem J, Wester P, Opperhuizen A. Hazardous compounds in tobacco smoke. Int J Environ Res Public Health. 2011;8(2):613-28. Review.)which, when inhaled by the passive smoker, contains six times more nicotine, four times more tar, seven times more carbon monoxide, and 73 times more ammonia than that inhaled by the active smoker.(³3. Valsoni BC. Efeitos do tabagismo passivo associado ao exercício físico durante prenhez e lactação [dissertação]. Presidente Prudente (SP): Faculdade de Ciências e Tecnologia, Universidade Estadual Paulista; 2010 [citado 2017 Jan 5]. Disponível em: https://repositorio.unesp.br/bitstream/handle/11449/87315/valsoni_bcg_me_prud.pdf?sequence=1&isAllowed=y
https://repositorio.unesp.br/bitstream/h... )

A comparative study performed by Dülger et al.,(⁴4. Dülger H, Dönder A, Sekeroğlu MR, Erkoç R, Ozbay B. Investigation of the relationship between serum levels of cotinine and the renal function in active and passive smokers. Ren Fail. 2011;33(5):475-9.) among a group of family members of smokers and volunteers who were not subjected to cigarette smoke, demonstrated renal functions are compromised by active smoking. However, Elihimas Júnior et al.,(⁵5. Elihimas Júnior UF, Elihimas HC, Lemos VM, Leão MA, Sá MP, França EE, et al. Smoking as risk factor for chronic kidney disease: systematic review. J Bras Nefrol. 2014;36(4):519-28. Review.) pointed out exposure to cigarette smoke can also be a potent kidney toxic agent. Jain et al.,(⁶6. Jain G, Jaimes EA. Nicotine signaling and progression of chronic kidney disease in smokers. Biochem Pharmacol. 2013;86(8):1215-23. Review.) have demonstrated that nicotine is a powerful stimulus for human mesangial cell proliferation and fibronectin production, aggravating glomerular injury.

Thus, smoking and circulating nicotine negatively influence the structures responsible for glomerular filtration, but the association between passive smoking and morphofunctional alterations of these structures, due to this exposure, has not been fully clarified in the literature yet, and this is the main objective of the present study.

OBJECTIVE

To analyze the morphological, structural, and functional aspects in kidneys of rats after passive inhalation of cigarette smoke.

METHODS

Animal care

Animal care and housing were in accordance with the National and Institutional Guidelines for Animal Welfare, established by the Colégio Brasileiro de Experimentação Animal (COBEA) [Brazilian College of Animal Experimentation] and the Conselho Nacional de Controle de Experimentação Animal (CONCEA) [National Council for the Control of Animal Experimentation]. All use of animals was reviewed and approved by the Ethics Committee on Animal Experimentation (process 286/2015). Hence, efforts were made to minimize suffering, discomfort, and number of animals used, treating them humanely.

Study design

An experimental study composed of male rats (Rattus norvegicus albinus), 8-week-old, weighing an average of 260g, divided into Control Group (CG) and Passive Smoker Group (SG). The CG and SG were subdivided into CG 7 days (n=10), SG 7 days (n=10), CG 28 days (n=10), and GT 28 days (n=10). The animals of both groups were kept in the vivarium of the Faculdade de Medicina de Jundiaí (FMJ), from November 2015 to January 2016, in separate rooms, two per box, under room temperature between 22±2°C, and a light/dark cycle of 12 hours. The animals’ weight gain (g), and intake of filtered water (mL), and feed (g) ad libitum (Nuvilab^®; energy value: 339kcal=1418kJ 100.0%; carbohydrates 54g or 63.4%; proteins 22g or 25.9%; and lipids 4g or 10.6% - amounts per 100g serving and percentage of total energy value) were monitored throughout the experiment. The differences between the amount offered and the amount neglected by the animal were used to calculate the average intake.

To adapt to cigarette smoke, the animals of the SG were gradually exposed to burning cigarettes, which occurred in twos, up to 40 cigarettes per day (high yield; tar: 10mg; nicotine: 0.8mg; carbon monoxide: 10mg) for periods ranging from seven to 28 days. The burning occurred in an automated smoking machine (SM-MC-01), programmed to start burning cigarettes every 6 hours, with the burning of 10 cigarettes per cycle. The cigarette smoke was aspirated by the inflow system of the ventilation rack, the so-called “smoking room” (Figure 1), and distributed homogeneously inside the sealed boxes of the animals. Carbon dioxide was measured inside the boxes and in the environment where the CG and SG animals were kept, using a calibrated carbon dioxide meter (AZ Instruments, model AZ 77535, serial number 10109975) (certificate 00948/2016).

Figure 1
Photograph of the ventilation inlet system and the smoking machine. (A) Panoramic photograph of the ventilation support inlet system (smoking room). At top left is the blower in the center of the smoking machine, and at right is the exhaust fan. See also the back of the ducts and, in front, the sealed boxes attached to the system; (B) The smoking machine filled with 200 cigarettes, and, on the left, the inlet of the inflow system; (C) Detail of the smoking machine with the resistance system for automatic burning of cigarettes

Urine volume and analysis of the biochemical parameters

On the 6^th and 27^th days, the animals were placed in metabolic cages for collection of 24-hour urine. Soon after, they were weighed, anesthetized, euthanized by prolonged anesthesia, and the kidneys and blood were collected. Microalbuminuria was measured by immunoturbidimetry, through spectrophotometric analysis. The measurement of plasma creatinine clearance (reference value: 0.58±0.24mg/dL)(⁷7. Dantas JA, Ambiel CR, Cuman RK, Baroni S, Bersani-Amado CA. Valores de referência de alguns parâmetros fisiológicos de ratos do Biotério Central da Universidade Estadual de Maringá, Estado do Paraná. Acta Sci Health Sci. 2006;28(2):165-70.) and urinary creatinine clearance (reference value: 67.2±12.8mg/dL)(⁷7. Dantas JA, Ambiel CR, Cuman RK, Baroni S, Bersani-Amado CA. Valores de referência de alguns parâmetros fisiológicos de ratos do Biotério Central da Universidade Estadual de Maringá, Estado do Paraná. Acta Sci Health Sci. 2006;28(2):165-70.) was performed by the Jaffé method.(⁸8. Teshima CA, Watanabe M, Fonseca CD, Vattimo MF. Simvastatin and acute ischemic renal injury in rats. Acta Paul Enferm. 2012;25(1):86-9.) For creatinine and glucose analyses (reference value: 108±17.4mg/dL),(⁷7. Dantas JA, Ambiel CR, Cuman RK, Baroni S, Bersani-Amado CA. Valores de referência de alguns parâmetros fisiológicos de ratos do Biotério Central da Universidade Estadual de Maringá, Estado do Paraná. Acta Sci Health Sci. 2006;28(2):165-70.) samples were centrifuged at 3,000rpm, for ten minutes, at 4°C to obtain serum. Enzymatic kits were then used for the measurements at Laborlab for creatinine, Bioclin for glucose, and Analisa for microalbuminuria.

Weights, dimensions, and histology of kidneys

The kidneys obtained from the animals were dissected and weighed on an analytical scale (model AB204, Mettler Toledo, Barueri, SP, Brazil). The kidney dimensions (length, width, and height) were obtained using a pachymeter, and their radii (r) were used to determine the kidney volume in cubic centimeters using the formula vol=4/3π (r1.r2.r3), used to calculate the volume of an ellipse.(⁹9. Araújo LM, Serigiolle LC, Gomes HM, Rodrigues DA, Lopes CM, Leme PL. Volume calculation of rats’ organs and its application in the validation of the volume relation between the abdominal cavity and the hernial sac in incisional hernias with “loss of abdominal domain”. Arq Bras Cir Dig. 2014;27(3):177-81.) For histological analysis, the right kidney (RK) was cut horizontally between the renal poles, and the left kidney (LK) had cross-section, cranial, and caudal to the kidney hilum sections, with the central section used for the analyses. The tissue sections were embedded in paraffin, cut approximately 4μm thick, and stained with hematoxylin-eosin (HE) and periodic acid Schiff (PAS).

Morphometry and stereology

The measurements of the renal cortex were obtained with a calibrated millimeter eyepiece, attached to a Motic optical microscope with 4X objective lens, on histological slides of RK and LK, stained in HE.

The entire morphoquantitative study of the tissues at the structural level was performed using the Motic Images Plus 2.0 software, for the analyses and digitalization of the histological sections. To quantify the glomerular density of the groups, images of the renal cortex were captured with a 4X objective, on histological slides stained in HE. On the image, in 15 fields of the LK and 20 fields of the RK, a test system was inserted, formed by the reticule and the referred intersections, which totaled 100 points, counting those that focused on the glomeruli, and excluding those focusing on the dashed lines (Figure 2). The glomerular density in relation to the test system was calculated as follows: Vv[glom] =p/P (Vv[glom]), with glomerular density in percentage; p are the points on the glomeruli, and P is the total number of points in the test system.(¹⁰10. Lacerda CA. Fisiologia e fisiopatologia: estereologia do rim: determinação do Vv, Nv e volume médio do glomérulo. Braz J Nephrol. 2000;22(2):103-9.)

Figure 2
Schematic photomicrographs of the glomerular density measurement. (A) Schematic representation of the test system; (B) Enlarged photomicrograph of the schematic representation of the calibration of the points affecting the test system. Blue dashes represent points on the glomeruli, and dashed lines on the test system represent points prohibited for counting. 4X hematoxylin-eosin staining. Control Group 14, right kidney

To calculate the glomerular and capsular diameters on the images captured with 40X objective on the slides stained with PAS, lines were drawn between the ends of these structures with the value calculated by the program (in µm). The mean diameter was obtained after averaging the largest and smallest diameter of the structures mentioned, in 40 renal corpuscles in the RK and 30 in the LK, in which vascular and/or urinary poles were observed (Figure 3A). The capsular spaces were obtained by the difference between their values.

Figure 3
Schematic photomicrographs of the measurement of renal corpuscle diameters and mesangial density. (A) Enlarged photomicrograph of the glomerulus, showing at L1 and L2 the glomerular diameter measurements, and at L3 and L4 the glomerular capsule diameter measurements. Staining was done with Schiff’s periodic acid staining, 40X, Smoker Group 21, left kidney; (B) Schematic photomicrograph of the mesangial density measurement. Blue traces represent dots that are concentrated in the glomeruli, and red traces represent dots in the nucleus of mesangial cells. Schiff’s periodic acid staining, 60X, Smoker Group 21, left kidney

In these same glomeruli, now with a 60X objective, the test system was inserted again, and the points that appeared on the glomerulus were counted. Immediately after, the points that were incident on the nuclei of the mesangial cell were counted;(⁹9. Araújo LM, Serigiolle LC, Gomes HM, Rodrigues DA, Lopes CM, Leme PL. Volume calculation of rats’ organs and its application in the validation of the volume relation between the abdominal cavity and the hernial sac in incisional hernias with “loss of abdominal domain”. Arq Bras Cir Dig. 2014;27(3):177-81.) those were grouped within a mesangial space, surrounded by mesangial matrix between the glomerular capillary loops(¹¹11. Soares MF. An update on pathology of IgA nephropathy. J Bras Nefrol. 2016;38(4):435-40. Review.) (Figure 3B). The volume fractions occupied by mesangial cell relative to the test system (glomerulus) were calculated as follows: Vv[mesg] = p/P (Vv[mesg], with mesangial volume density given as a percentage, p indicative of the points on the mesangial cell nuclei, and P corresponding to the total number of points in the test system.(⁸8. Teshima CA, Watanabe M, Fonseca CD, Vattimo MF. Simvastatin and acute ischemic renal injury in rats. Acta Paul Enferm. 2012;25(1):86-9.)

Statistical analysis

The statistical analysis was carried out with the objective of making comparisons between the CG and the SG, as well as intra-group comparisons, for each of the variables studied, using means and standard deviations. The data were submitted to analysis of variance (ANOVA). The assumption of homogeneity of variances was verified by applying Tukey’s multiple comparisons test. The significance level adopted for all tests was p≤0.05. The software used for analysis was Biostat 5.3 (Instituto de Desenvolvimento Sustentável Mamirauá, Belém, PA, Brazil), and comparisons were made, both between CG and SG, and intra-group.

RESULTS

Carbon dioxide levels (part per million)

The efficacy of the smoking room equipment in generating and insufflating smoke was confirmed by detection of carbon dioxide levels. The initial mean value before cigarette burning was 620.8 parts per million (ppm) in the SG environment, which was close to the mean value obtained in the CG environment (571.8ppm). As the cigarettes were lit and smoke insufflated into the boxes, carbon dioxide levels increased progressively from a minimum mean value of 616.6ppm to a maximum mean value of 1,267.0ppm (p≤0.01).

Body weight gain and intake

The SG animals showed lower body weight gain, and lower feed and water intake during the periods studied (Table 1).

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Table 1
Body weight gain and intake

Morphometry: kidney weights and dimensions

There were significant reductions in the mean values for kidney weight, kidney dimensions (length, width, and height), kidney volume, and cortical thickness in the SG animals during the periods studied. There was no difference as to the length of the RK in both periods, and the height of the LK in the seven day period (Table 2).

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Table 2
Kidney weight and dimensions at seven and 28 days

Morphometry and stereology of renal corpuscles

As for the glomerular volume density and the glomerular and capsular diameters, the mean values observed in the SG kidneys were significantly lower. Regarding capsular spaces, the mean values observed in the SG were significantly higher during the period of 28 days. Regarding the density of mesangial volume occupied by mesangial cell in glomeruli, the mean values in the SG were significantly higher (Table 3 and Figure 4).

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Table 3
Glomerular volume density, mesangial volume density, and glomerular corpuscle diameter at seven and 28 days

Figure 4
Photomicrographs of the cortical region of the kidneys at seven and 28 days. (A and C) Control Group; (B and D) Smoker Group. Note that, in B and D, there are smaller glomeruli with mesangial cells in higher concentration, when compared to A and C. Note glomerular capsule, distal convoluted tubule, proximal convoluted tubule, urinary pole, vascular pole, afferent arteriole, and mesangial cell nucleus

Urine volume and analysis of biochemical parameters

The urinary volume of the SG animals was significantly lower at seven days, and there was no difference at 28 days. The glucose, creatinine, and microalbuminuria levels of the SG animals were significantly higher, and the urinary creatinine levels and creatinine clearance rate in the SG animals were significantly lower during the periods studied (Table 4).

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Table 4
Urine volume and analysis of biochemical parameters

DISCUSSION

In the present study, carbon dioxide was used to verify the degree of environmental pollution from cigarette smoke. The levels of this gas in the boxes of the SG animals were similar to those found by Colli Neto et al.,(¹²12. Colli Neto JA, Zen Júnior JH, Del Negro A, Andreollo NA, Araujo MR, Tincani AJ. Tobacco experimental model to induce urinary bladder neoplasms. Rev Col Bras Cir. 2014;41(1):56-60.) who observed levels of carbon dioxide concentration above 999ppm. This indicates the components present in cigarette smoke circulated and the animals inhaled them. Furthermore, the work of Robello(¹³13. Robello EC. Análise morfoquantitativa da artéria basilar e da artéria cerebral média em ratos expostos ao tabagismo passivo [dissertação]. Jundiaí: Faculdade de Medicina de Jundiaí; 2014.) using a similar method of exposure identified high levels of cotinine (nicotine metabolite) in the serum of animals from the SG.

Because of this exposure, the SG animals presented with lower weight gain in the periods studied, due to the lower intake of water and feed. Nicotine inhalation by cigarette smoke alters the metabolism, promoting increased heat production and oxygen consumption, which stimulates the thyroid-stimulating hormone (TSH) with consequent increased metabolism, and higher levels of glucose and cholesterol in the blood.(¹⁴14. Boor P, Casper S, Celec P, Hurbánková M, Beno M, Heidland A, et al. Renal, vascular and cardiac fibrosis in rats exposed to passive smoking and industrial dust fibre amosite. J Cell Mol Med. 2009;13(11-12):4484-91.) It also causes an acute elevation of dopamine and serotonin concentrations in the brain, thus inhibiting food intake.(¹⁵15. Chatkin R, Chatkin JM. Smoking and changes in body weight: can physiopathology and genetics explain this association? J Bras Pneumol. 2007;33(6):712-9. Review.) One of the hypotheses suggested for this is the moderate hyperglycemic level in smokers,(¹⁶16. Tweed JO, Hsia SH, Lutfy K, Friedman TC. The endocrine effects of nicotine and cigarette smoke. Trends Endocrinol Metab. 2012;23(7):334-42. Review.) a fact observed in the present study and in the studies by Sinzato et al.(¹⁷17. Sinzato YK, Lima PH, Santos CE, Campos KE, Rudge MV, Damasceno DC. Association of diabetes and cigarette smoke exposure on the glycemia and liver glycogen of pregnant Wistar rats. Acta Cir Bras. 2008;23(6):481-5.)

In the study with rats exposed to smoking as from the intrauterine period, Schiffner(¹⁸18. Schiffner MD. Estabelecimento de um modelo animal de exposição à fumaça do tabaco durante a gestação, investigação de alterações na programação fetal e suas repercussões metabólicas na vida adulta [tese]. Porto Alegre (RS): Faculdade de Medicina, Universidade Federal do Rio Grande do Sul; 2012. 101 f. [citado 2017 Jan 5]. Disponível em: https://www.lume.ufrgs.br/bitstream/handle/10183/56667/000859243.pdf?sequence=1&isAllowed=y
https://www.lume.ufrgs.br/bitstream/hand... )observed that analysis of the glucose tolerance test showed resistance to insulin action and higher glucose peaks in this group when compared to controls, suggesting that smokers have greater difficulty in glucose uptake due to the lower availability of insulin, the lower number and/or function of insulin receptors, or the lower capacity to induce the intracellular signaling cascade, which facilitates glucose uptake.

As a result of these factors, kidney weights and dimensions in the present study were affected, culminating in smaller kidney volumes, a fact also observed in the experimental study by Dündar et al.(¹⁹19. Dündar M, Kocak I, Culhaci N. Effects of long-term passive smoking on the diameter of glomeruli in rats: Histopathological evaluation. Nephrology (Carlton). 2004;9(2):53-7.) However, although certain morphological alterations may not mean impairment of renal function, this association seems to follow in a directly proportional manner in smoking, since significant atrophy was observed when assessing the cortical thickness in the SG. In fact, the relation between cortical thickness and kidney function has been suggested, especially when there is a proportional reduction of glomeruli,(²⁰20. Zarzecki M, Adamczak M, Wystrychowski A, Gross ML, Ritz E, Więcek A. Exposure of pregnant rats to cigarette-smoke condensate causes glomerular abnormalities in offspring. Kidney Blood Press Res. 2012;36(1):162-71.) also observed in the present study, with a significant reduction of the dimensions of the renal corpuscle diameter. However, the capsular space increased in the SG, with longer exposure time, probably due to reductions in glomerular diameter, allowing the resulting decrease in glomerular filtration rate (GFR).(¹⁹19. Dündar M, Kocak I, Culhaci N. Effects of long-term passive smoking on the diameter of glomeruli in rats: Histopathological evaluation. Nephrology (Carlton). 2004;9(2):53-7.)

In the evaluation of mesangial volume density, there was a significant increase in the SG animals. The mesangial cell that help and modulate the GFR and the surface area of the glomerulus, thanks to their ability to contract and relax in response to vasoactive drugs, may suffer significant proliferation, with glomerular sclerosis and tubulo-interstitial fibrosis in animals in response to the glomerular endothelial lesions caused by smoking.(²¹21. Rezonzew G, Chumley P, Feng W, Hua P, Siegal GP, Jaimes EA. Nicotine exposure and the progression of chronic kidney disease: role of the α7-nicotinic acetylcholine receptor. Am J Physiol Renal Physiol. 2012;303(2):F304-12.,²²22. Younes-Ibrahim M. Mesangial cells: renal function protagonists or coadjuvants? J Bras Nefrol. 2013;35(4):248-9.)

Due to the morphological changes observed, as well as a lower water consumption by the SG animals, also observed in the studies by Gonçalves-Silva et al.,(²³23. Gonçalves-Silva RM, Lemos-Santos MG, Botelho C. Influência do tabagismo no ganho ponderal, crescimento corporal, consumo alimentar e hídrico de ratos. J Pneumol. 1997;23(3):124-30.) the biochemical parameters of blood and urine analysis also changed in the SG, providing subsidies to understand the possible damage to kidney function, since the levels of creatinine, urinary creatinine, and urinary volume, used to determine the creatinine clearance rate to estimate the GFR, were significantly lower. Smoking promotes a significant increase in the albumin-creatinine ratio, with changes in glomerular capillary pressure and kidney function,(²⁴24. Hallan SI, Orth SR. Smoking is a risk factor in the progression to kidney failure. Kidney Int. 2011;80(5):516-23.) and there are few studies correlating nicotine present in the bloodstream of passive smokers with kidney diseases, especially regarding acute exposure.(²⁵25. Narkiewicz K. Second-hand smoke - a license to kill due to expire. Nephrol Dial Transplant. 2007;22(6):1508-11. Review.)

Thus, the acute action of circulating nicotine may be related to glomerular endothelial dysfunction, since the persistent levels of microalbuminuria, significantly elevated in this study, determine and classify the onset and progression of nephropathy, and express a risk factor for endothelial dysfunction and injury in the macro- and microcirculation.(²⁶26. Lagranha CJ, Fiorino P, Casarini DE, Schaan BD, Irigoyen MC. Bases moleculares da glomerulopatia diabética. Arq Bras Endocrinol Metabol. 2007;51(6):901-12. Review.) Cooper(²⁷27. Cooper RG. Effect of tobacco smoking on renal function. Indian J Med Res. 2006;124(3):261-8. Review.) demonstrated nicotine accelerates nephropathies, which are detected by increasing microalbuminuria with progression to proteinuria, concluding that active and passive smoking are toxic to kidney function.

CONCLUSION

Exposure and passive inhalation of cigarette smoke by the animals caused morphological and structural changes in their kidneys. Coupled with changes in biochemical parameters due to exposure, the result was a decreased glomerular filtration rate, demonstrating exposure to secondhand smoke can compromise kidney function, with similar effects to those of active smoking.

ACKNOWLEDGMENTS

To the Núcleo de Apoio à Pesquisa e Docência da Faculdade de Medicina de Jundiaí.

REFERENCES

¹
Brasil. Ministério da Saúde. Instituto Nacional de Câncer (INCA). Tabagismo. Rio de Janeiro: INCA; 2020 [citado 2020 Nov 13]. Disponível em: https://www.inca.gov.br/tabagismo
» https://www.inca.gov.br/tabagismo
²
Talhout R, Schulz T, Florek E, van Benthem J, Wester P, Opperhuizen A. Hazardous compounds in tobacco smoke. Int J Environ Res Public Health. 2011;8(2):613-28. Review.
³
Valsoni BC. Efeitos do tabagismo passivo associado ao exercício físico durante prenhez e lactação [dissertação]. Presidente Prudente (SP): Faculdade de Ciências e Tecnologia, Universidade Estadual Paulista; 2010 [citado 2017 Jan 5]. Disponível em: https://repositorio.unesp.br/bitstream/handle/11449/87315/valsoni_bcg_me_prud.pdf?sequence=1&isAllowed=y
» https://repositorio.unesp.br/bitstream/handle/11449/87315/valsoni_bcg_me_prud.pdf?sequence=1&isAllowed=y
⁴
Dülger H, Dönder A, Sekeroğlu MR, Erkoç R, Ozbay B. Investigation of the relationship between serum levels of cotinine and the renal function in active and passive smokers. Ren Fail. 2011;33(5):475-9.
⁵
Elihimas Júnior UF, Elihimas HC, Lemos VM, Leão MA, Sá MP, França EE, et al. Smoking as risk factor for chronic kidney disease: systematic review. J Bras Nefrol. 2014;36(4):519-28. Review.
⁶
Jain G, Jaimes EA. Nicotine signaling and progression of chronic kidney disease in smokers. Biochem Pharmacol. 2013;86(8):1215-23. Review.
⁷
Dantas JA, Ambiel CR, Cuman RK, Baroni S, Bersani-Amado CA. Valores de referência de alguns parâmetros fisiológicos de ratos do Biotério Central da Universidade Estadual de Maringá, Estado do Paraná. Acta Sci Health Sci. 2006;28(2):165-70.
⁸
Teshima CA, Watanabe M, Fonseca CD, Vattimo MF. Simvastatin and acute ischemic renal injury in rats. Acta Paul Enferm. 2012;25(1):86-9.
⁹
Araújo LM, Serigiolle LC, Gomes HM, Rodrigues DA, Lopes CM, Leme PL. Volume calculation of rats’ organs and its application in the validation of the volume relation between the abdominal cavity and the hernial sac in incisional hernias with “loss of abdominal domain”. Arq Bras Cir Dig. 2014;27(3):177-81.
¹⁰
Lacerda CA. Fisiologia e fisiopatologia: estereologia do rim: determinação do Vv, Nv e volume médio do glomérulo. Braz J Nephrol. 2000;22(2):103-9.
¹¹
Soares MF. An update on pathology of IgA nephropathy. J Bras Nefrol. 2016;38(4):435-40. Review.
¹²
Colli Neto JA, Zen Júnior JH, Del Negro A, Andreollo NA, Araujo MR, Tincani AJ. Tobacco experimental model to induce urinary bladder neoplasms. Rev Col Bras Cir. 2014;41(1):56-60.
¹³
Robello EC. Análise morfoquantitativa da artéria basilar e da artéria cerebral média em ratos expostos ao tabagismo passivo [dissertação]. Jundiaí: Faculdade de Medicina de Jundiaí; 2014.
¹⁴
Boor P, Casper S, Celec P, Hurbánková M, Beno M, Heidland A, et al. Renal, vascular and cardiac fibrosis in rats exposed to passive smoking and industrial dust fibre amosite. J Cell Mol Med. 2009;13(11-12):4484-91.
¹⁵
Chatkin R, Chatkin JM. Smoking and changes in body weight: can physiopathology and genetics explain this association? J Bras Pneumol. 2007;33(6):712-9. Review.
¹⁶
Tweed JO, Hsia SH, Lutfy K, Friedman TC. The endocrine effects of nicotine and cigarette smoke. Trends Endocrinol Metab. 2012;23(7):334-42. Review.
¹⁷
Sinzato YK, Lima PH, Santos CE, Campos KE, Rudge MV, Damasceno DC. Association of diabetes and cigarette smoke exposure on the glycemia and liver glycogen of pregnant Wistar rats. Acta Cir Bras. 2008;23(6):481-5.
¹⁸
Schiffner MD. Estabelecimento de um modelo animal de exposição à fumaça do tabaco durante a gestação, investigação de alterações na programação fetal e suas repercussões metabólicas na vida adulta [tese]. Porto Alegre (RS): Faculdade de Medicina, Universidade Federal do Rio Grande do Sul; 2012. 101 f. [citado 2017 Jan 5]. Disponível em: https://www.lume.ufrgs.br/bitstream/handle/10183/56667/000859243.pdf?sequence=1&isAllowed=y
» https://www.lume.ufrgs.br/bitstream/handle/10183/56667/000859243.pdf?sequence=1&isAllowed=y
¹⁹
Dündar M, Kocak I, Culhaci N. Effects of long-term passive smoking on the diameter of glomeruli in rats: Histopathological evaluation. Nephrology (Carlton). 2004;9(2):53-7.
²⁰
Zarzecki M, Adamczak M, Wystrychowski A, Gross ML, Ritz E, Więcek A. Exposure of pregnant rats to cigarette-smoke condensate causes glomerular abnormalities in offspring. Kidney Blood Press Res. 2012;36(1):162-71.
²¹
Rezonzew G, Chumley P, Feng W, Hua P, Siegal GP, Jaimes EA. Nicotine exposure and the progression of chronic kidney disease: role of the α7-nicotinic acetylcholine receptor. Am J Physiol Renal Physiol. 2012;303(2):F304-12.
²²
Younes-Ibrahim M. Mesangial cells: renal function protagonists or coadjuvants? J Bras Nefrol. 2013;35(4):248-9.
²³
Gonçalves-Silva RM, Lemos-Santos MG, Botelho C. Influência do tabagismo no ganho ponderal, crescimento corporal, consumo alimentar e hídrico de ratos. J Pneumol. 1997;23(3):124-30.
²⁴
Hallan SI, Orth SR. Smoking is a risk factor in the progression to kidney failure. Kidney Int. 2011;80(5):516-23.
²⁵
Narkiewicz K. Second-hand smoke - a license to kill due to expire. Nephrol Dial Transplant. 2007;22(6):1508-11. Review.
²⁶
Lagranha CJ, Fiorino P, Casarini DE, Schaan BD, Irigoyen MC. Bases moleculares da glomerulopatia diabética. Arq Bras Endocrinol Metabol. 2007;51(6):901-12. Review.
²⁷
Cooper RG. Effect of tobacco smoking on renal function. Indian J Med Res. 2006;124(3):261-8. Review.

Publication Dates

Publication in this collection
03 Nov 2021
Date of issue
2021

History

Received
8 July 2020
Accepted
15 Mar 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Robello EC. Análise morfoquantitativa da artéria basilar e da artéria cerebral média em ratos expostos ao tabagismo passivo [dissertação]. Jundiaí: Faculdade de Medicina de Jundiaí; 2014.

[14] ¹⁴
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[15] ¹⁵
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[16] ¹⁶
Tweed JO, Hsia SH, Lutfy K, Friedman TC. The endocrine effects of nicotine and cigarette smoke. Trends Endocrinol Metab. 2012;23(7):334-42. Review.

[17] ¹⁷
Sinzato YK, Lima PH, Santos CE, Campos KE, Rudge MV, Damasceno DC. Association of diabetes and cigarette smoke exposure on the glycemia and liver glycogen of pregnant Wistar rats. Acta Cir Bras. 2008;23(6):481-5.

[18] ¹⁸
Schiffner MD. Estabelecimento de um modelo animal de exposição à fumaça do tabaco durante a gestação, investigação de alterações na programação fetal e suas repercussões metabólicas na vida adulta [tese]. Porto Alegre (RS): Faculdade de Medicina, Universidade Federal do Rio Grande do Sul; 2012. 101 f. [citado 2017 Jan 5]. Disponível em: https://www.lume.ufrgs.br/bitstream/handle/10183/56667/000859243.pdf?sequence=1&isAllowed=y
» https://www.lume.ufrgs.br/bitstream/handle/10183/56667/000859243.pdf?sequence=1&isAllowed=y

[19] ¹⁹
Dündar M, Kocak I, Culhaci N. Effects of long-term passive smoking on the diameter of glomeruli in rats: Histopathological evaluation. Nephrology (Carlton). 2004;9(2):53-7.

[20] ²⁰
Zarzecki M, Adamczak M, Wystrychowski A, Gross ML, Ritz E, Więcek A. Exposure of pregnant rats to cigarette-smoke condensate causes glomerular abnormalities in offspring. Kidney Blood Press Res. 2012;36(1):162-71.

[21] ²¹
Rezonzew G, Chumley P, Feng W, Hua P, Siegal GP, Jaimes EA. Nicotine exposure and the progression of chronic kidney disease: role of the α7-nicotinic acetylcholine receptor. Am J Physiol Renal Physiol. 2012;303(2):F304-12.

[22] ²²
Younes-Ibrahim M. Mesangial cells: renal function protagonists or coadjuvants? J Bras Nefrol. 2013;35(4):248-9.

[23] ²³
Gonçalves-Silva RM, Lemos-Santos MG, Botelho C. Influência do tabagismo no ganho ponderal, crescimento corporal, consumo alimentar e hídrico de ratos. J Pneumol. 1997;23(3):124-30.

[24] ²⁴
Hallan SI, Orth SR. Smoking is a risk factor in the progression to kidney failure. Kidney Int. 2011;80(5):516-23.

[25] ²⁵
Narkiewicz K. Second-hand smoke - a license to kill due to expire. Nephrol Dial Transplant. 2007;22(6):1508-11. Review.

[26] ²⁶
Lagranha CJ, Fiorino P, Casarini DE, Schaan BD, Irigoyen MC. Bases moleculares da glomerulopatia diabética. Arq Bras Endocrinol Metabol. 2007;51(6):901-12. Review.

[27] ²⁷
Cooper RG. Effect of tobacco smoking on renal function. Indian J Med Res. 2006;124(3):261-8. Review.

Variables	Groups

	7 days		28 days

	CG	SG	CG	SG
Weight, g	289.1±18.4	265.0±17.2*	377.6±32.7	344.2±29.0^†
Feed, g	194.5±1.5	103.0±6.9*	199.5±14.4	148.3±11.8*
Water, mL	288.0±28.4	178.0±17.8*	286.0±24.3	252.3±13.5*

Variables	Groups

	Control		Smoker

	RK	LK	RK	LK
Kidney weight, g
7 days	1.51±0.06	1.45±0.03	1.28±0.16*	1.23±0.17^†
28 days	1.79±0.06	1.68±0.16	1.41±0.21^†	1.34±0.18^†
Length, mm
7 days	18.8±0.45	20.7±0.57	18.5±1.02	18.7±0.56^†
28 days	19.8±0.26	20.7±0.47	19.7±0.93	19.7±1.09*
Width, mm
7 days	12.3±0.48	11.8±0.27	10.5±0.51^†	9.7±0.29^†
28 days	12.8±0.29	12.4±0.33	11.7±0.82^†	11.1±0.36^†
Height, mm
7 days	9.6±0.61	8.8±0.07	8.2±0.65*	8.6±0.11
28 days	9.5±0.61	9.4±0.40	8.6±0.91*	8.7±0.52*
Kidney volume, cm³
7 days	1.15±0.08	1.13±0.07	0.84±0.11^†	0.82±0.11^†
28 days	1.27±0.08	1.27±0.05	1.04±0.18^†	1.00±0.12^†
Cortical thickness, mm
7 days	2.31±0.12	2.19±0.08	2.00±0.10^†	1.93±0.07^†
28 days	2.36±0.13	2.26±0.10	2.10±0.15^†	2.13±0.03^†

Variables	Groups

	Control		Smoker

	RK	LK	RK	LK
Glomerular volume density
7 days	4.8±0.18	4.8±0.20	3.7±0.30*	4.0±0.18*
28 days	5.1±0.22	5.1±0.21	4.2±0.24*	4.3±0.17*
Mesangial volume density
7 days	16.2±1.4	12.1±1.2	18.8±1.9^†	18.2±2.1*
28 days	11.2±0.7	11.3±0.4	15.1±1.3*	14.2±1.6*
Glomerulus, µm
7 days	88.6±1.8	86.9±2.7	79.8±1.8*	81.1±3.3^†
28 days	104.6±4.6	100.7±7.3	88.6±4.6*	86.7±1.8*
Glomerulus, µm
7 days	103.2±3.4	102.0±2.8	95.6±3.2*	96.7±3.9^†
28 days	115.5±6.4	112.5±7.0	105.3±5.9^†	104.4±2.5^†
Glomerular capsule, µm
7 days	14.6±2.5	15.1±1.4	16.7±2.0	15.6±1.0
28 days	10.9±3.1	11.8±1.6	16.7±2.5^†	17.7±1.8^†

Variables	Groups

	7 days		28 days

	CG	SG	CG	SG
Urine volume, mL	14.5±8.0	10.6±10.0*	10.7±6.7	11.6±9.2
Glucose, mg/dL	93.8±17.0	133.6±32.2*	96.2±22.3	118.4±17.5^†
Creatinine, mg/dL	0.61±0.04	0.72±0.15^†	0.68±0.07	0.84±0.06*
Urinary creatinine, mg/dL	110.7±62.3	55.9±29.9^†	181.0±69.1	115.9±66.6^†
Creatinine clearance, mL/min	1.43±0.60	0.45±0.40*	1.65±0.54	0.75±0.30*
Microalbum, mg/L	0.47±0.23	6.37±2.2*	0.41±0.20	4.45±1.50*