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01-12-2021 | Osteoporosis | Original Article

The influence of snuff and smoking on bone accretion in late adolescence. The Tromsø study, Fit Futures

Authors: Ole Andreas Nilsen, Nina Emaus, Tore Christoffersen, Anne Winther, Elin Evensen, Gyrd Thrane, Anne-Sofie Furberg, Guri Grimnes, Luai Awad Ahmed

Published in: Archives of Osteoporosis | Issue 1/2021

Abstract

Summary

Areal bone mineral density (aBMD) predicts future fracture risk. This study explores associations between use of tobacco and bone accretion in Norwegian adolescents. Our results indicate that use of snuff is negatively associated with accretion of aBMD in adolescence and may be a signal of increased future fracture risk.

Purpose

Bone mineral accrual in childhood and adolescence is a long-term primary preventive strategy of osteoporosis. Areal bone mineral density (aBMD) is a surrogate measure of bone strength and a predictor of fracture risk. The aim of this population-based 2-year follow-up cohort study was to explore associations between use of snuff and smoking and changes (∆) in aBMD in Norwegian girls and boys aged 15–17 years at baseline.

Methods

The first wave of the Tromsø study, Fit Futures was conducted from 2010 to 2011. Femoral neck (FN), total hip (TH), and total body (TB) bone mineral content (BMC) and aBMD were measured by dual-energy X-ray absorptiometry. Information on use of snuff, smoking habits, and other lifestyle related variables were collected through self-administered questionnaires. Two years later, during 2012–2013, the measurements were repeated in the second wave. The present study included 349 girls and 281 boys and compared “non-users” (n = 243 girls, 184 boys) with “users” (n = 105 girls, 96 boys) of snuff and “non-smokers” (n = 327 girls, 249 boys) with “smokers” (n = 21 girls, 31 boys) using linear regression adjusted for age, baseline height and weight, change in height and weight, pubertal maturation, physical activity, ethnicity, alcohol consumption, diagnosis known to affect bone, and medication known to affect bone. The influence of “double use” on bone accretion was also explored.

Results

In girls, no associations between use of snuff and ∆aBMD were found. In boys, use of snuff was associated with reduced bone accretion in all ∆aBMD models. Sensitivity analysis with exclusion of “sometimes” users of snuff strengthened associations at femoral sites in girls and attenuated all associations in boys. In girls, no associations between smoking and ∆aBMD were found. In boys, only the association with TB ∆aBMD was significant in the fully adjusted models. In girls, “double users” analyses showed similar association to smoking. In boys, nearly all models showed statistically significant associations with a difference of ~ 1–2% in ∆aBMD between “non-users” and “double users” during 2 years of follow-up.

Conclusions

Our results indicate that tobacco use in late adolescence could be detrimental to bone accretion and may be a signal of increased fracture risk in adult life.

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Kanis JA, Oden A, McCloskey EV, Johansson H, Wahl DA, Cooper C et al (2012) A systematic review of hip fracture incidence and probability of fracture worldwide. Osteoporos Int 23(9):2239–2256CrossRef

Lofthus C, Osnes E, Falch J, Kaastad T, Nordsletten L, Stensvold I et al (2001) Epidemiology of hip fractures in Oslo. Norway Bone 29(5):413–418CrossRef

Di Iorgi N, Maruca K, Patti G, Mora S (2018) Update on bone density measurements and their interpretation in children and adolescents. Best Pract Res Clin Endocrinol Metab 32(4):477–498CrossRef

Cooper C, Westlake S, Harvey N, Javaid K, Dennison E, Hanson M (2006) Review: developmental origins of osteoporotic fracture. Osteoporos Int 17(3):337–347CrossRef

Baxter-Jones AD, Faulkner RA, Forwood MR, Mirwald RL, Bailey DA (2011) Bone mineral accrual from 8 to 30 years of age: an estimation of peak bone mass. J Bone Miner Res 26(8):1729–1739CrossRef

Bailey DA, McKay HA, Mirwald RL, Crocker PR, Faulkner RA (1999) A six-year longitudinal study of the relationship of physical activity to bone mineral accrual in growing children: the university of Saskatchewan bone mineral accrual study. J Bone Miner Res 14(10):1672–1679CrossRef

Weaver C, Gordon C, Janz K, Kalkwarf H, Lappe J, Lewis R et al (2016) The National Osteoporosis Foundation’s position statement on peak bone mass development and lifestyle factors: a systematic review and implementation recommendations. Osteoporos Int 27(4):1281–1386CrossRef

Dorn LD, Beal SJ, Kalkwarf HJ, Pabst S, Noll JG, Susman EJ (2013) Longitudinal impact of substance use and depressive symptoms on bone accrual among girls aged 11–19 years. J Adolesc Health 52(4):393–399CrossRef

Eleftheriou KI, Rawal JS, James LE, Payne JR, Loosemore M, Pennell DJ et al (2013) Bone structure and geometry in young men: the influence of smoking, alcohol intake and physical activity. Bone 52(1):17–26CrossRef

10.

Skretting A, Vedøy T, Lund K, Bye E (2016) Rusmidler i Norge 2016 [Drugs in Norway 2016]. Norwegian Institute of Public Health. Retrieved from https://www.fhi.no/publ/2017/rusmidler-i-norge-2016/

11.

Frederiksen N (2019) Smagstilsætningers betydning for brug af snus og e-cigaretter: Med fokus på unge og Norden. Nordens välfärdscenter/Nordic Welfare Centre. Retrieved from http://norden.divaportal.org/smash/record.jsf?pid=diva2%3A1283076&dswid=9860

12.

Larsen E, Rise J, Lund K (2013) Risk and protective factors of adolescent exclusive snus users compared to non-users of tobacco, exclusive smokers and dual users of snus and cigarettes. Addict Behav 38(7):2288–2294CrossRef

13.

Lund I, Scheffels J (2014) Smoking and snus use onset: exploring the influence of snus debut age on the risk for smoking uptake with cross-sectional survey data. Nicotine Tob Res 16(6):815–819CrossRef

14.

Kvaavik E (2018) Tobakk i Norge. Kvaavik E (2018) Tobakk i Norge. Retrieved from https://fhi.brage.unit.no/fhixmlui/bitstream/handle/11250/2582061/Kvaavik_2018_Tob.pdf?sequence=2&isAllowed=y

15.

Antoniewicz L (2018) Effects of cigarettes, e-cigarettes and Swedish snus on vascular function. Doctoral thesis, Karolinska Institutet, Sweden. Retrieved from https://openarchive.ki.se/xmlui/handle/10616/46371

16.

Al-Bashaireh AM, Haddad LG, Weaver M, Kelly DL, Chengguo X, Yoon S (2018) The effect of tobacco smoking on musculoskeletal health: a systematic review. J Environ Public Health 2018:4184190CrossRef

17.

Rudäng R, Darelid A, Nilsson M, Nilsson S, Mellström D, Ohlsson C et al (2012) Smoking is associated with impaired bone mass development in young adult men: a 5-year longitudinal study. J Bone Miner Res 27(10):2189–2197CrossRef

18.

Korkor AB, Eastwood D, Bretzmann C (2009) Effects of gender, alcohol, smoking, and dairy consumption on bone mass in Wisconsin adolescents. WMJ 108(4):181–188PubMed

19.

Lucas R, Fraga S, Ramos E, Barros H (2012) Early initiation of smoking and alcohol drinking as a predictor of lower forearm bone mineral density in late adolescence: a cohort study in girls. PloS one. 7(10):e46940CrossRef

20.

Lorentzon M, Mellström D, Haug E, Ohlsson C (2007) Smoking is associated with lower bone mineral density and reduced cortical thickness in young men. J Clin Endocrinol Metab 92(2):497–503CrossRef

21.

Winther A, Dennison E, Ahmed LA, Furberg AS, Grimnes G, Jorde R et al (2014) The Tromso study: Fit Futures: a study of Norwegian adolescents’ lifestyle and bone health. Arch Osteoporos 9(1):185CrossRef

22.

Nilsen OA, Ahmed LA, Winther A, Christoffersen T, Furberg AS, Grimnes G et al (2017) Changes and tracking of bone mineral density in late adolescence: the Tromso study, Fit Futures. Arch Osteoporos 12(1):37CrossRef

23.

Healthcare G (2010) Lunar enCORE Reference supplement. 11/2010. Retrieved from http://medicaloutfitter.net/wp-content/uploads/2014/09/enCORE_V13.5_EN_English.pdf

24.

Omsland TK, Emaus N, Gjesdal CG, Falch JA, Tell GS, Forsen L et al (2008) In vivo and in vitro comparison of densitometers in the NOREPOS study. J Clin Densitom 11(2):276–282CrossRef

25.

Petersen AC, Crockett L, Richards M, Boxer A (1988) A self-report measure of pubertal status: reliability, validity, and initial norms. J Youth Adolesc 17(2):117–133CrossRef

26.

Grimby G, Borjesson M, Jonsdottir IH, Schnohr P, Thelle DS, Saltin B (2015) The, “Saltin-Grimby Physical Activity Level Scale” and its application to health research. Scand J Med Sci Sports 25(Suppl 4):119–125CrossRef

27.

van Breukelen GJ (2013) ANCOVA versus CHANGE from baseline in nonrandomized studies: the difference. Multivariate Behav Res 48(6):895–922CrossRef

28.

Graham JW, Olchowski AE, Gilreath TD (2007) How many imputations are really needed? Some practical clarifications of multiple imputation theory. Prev Sci 8(3):206–213CrossRef

29.

W-Dahl A, Toksvig-Larsen S (2007) No delayed bone healing in Swedish male oral snuffers operated on by the hemicallotasis technique: a cohort study of 175 patients. Acta orthopaedica. 78(6):791–4CrossRef

30.

Bergström J, Keilani H, Lundholm C, Rådestad U (2006) Smokeless tobacco (snuff) use and periodontal bone loss. J Clin Periodontol 33(8):549–554CrossRef

31.

Singh S, Jain P, Singh PK, Reddy KS, Bhargava B (2020) White paper on smokeless tobacco & women’s health in India. Indian J Med Res 151(6):513–521CrossRef

32.

Bakan B, Özkan F, Sucakli MH, Bilal Ö, Gümüsalan Y (2012) The osteoporotic effect of maras powder (Turkish Smokeless Tobacco) consumption in healthy males. J Phys Ther Sci 24(12):1233–1237CrossRef

33.

Quandt SA, Spangler JG, Case LD, Bell RA, Belflower AE (2005) Smokeless tobacco use accelerates age-related loss of bone mineral density among older women in a multi-ethnic rural community. J Cross Cult Gerontol 20(2):109–125CrossRef

34.

Spangler JG, Quandt S, Bell RA (2001) Smokeless tobacco and osteoporosis: a new relationship? Med Hypotheses 56(5):553–557CrossRef

35.

Stepanov I, Jensen J, Hatsukami D, Hecht SS (2008) New and traditional smokeless tobacco: comparison of toxicant and carcinogen levels. Nicotine Tob Res 10(12):1773–1782CrossRef

36.

Dorn LD, Biro FM (2011) Puberty and its measurement: a decade in review. J Res Adolesc 21(1):180–195CrossRef

37.

Bratberg GH, Nilsen TI, Holmen TL, Vatten LJ (2007) Perceived pubertal timing, pubertal status and the prevalence of alcohol drinking and cigarette smoking in early and late adolescence: a population based study of 8950 Norwegian boys and girls. Acta Paediatr 96(2):292–295CrossRef

38.

Yoon V, Maalouf NM, Sakhaee K (2012) The effects of smoking on bone metabolism. Osteoporos Int 23(8):2081–2092CrossRef

39.

Yuhara S, Kasagi S, Inoue A, Otsuka E, Hirose S, Hagiwara H (1999) Effects of nicotine on cultured cells suggest that it can influence the formation and resorption of bone. Eur J Pharmacol 383(3):387–393CrossRef

40.

Tanaka H, Tanabe N, Kawato T, Nakai K, Kariya T, Matsumoto S et al (2013) Nicotine affects bone resorption and suppresses the expression of cathepsin K, MMP-9 and vacuolar-type H+-ATPase d2 and actin organization in osteoclasts. PloS one 8(3):e59402CrossRef

41.

Lunell E, Lunell M (2005) Steady-state nicotine plasma levels following use of four different types of Swedish snus compared with 2-mg nicorette chewing gum: a crossover study. Nicotine Tob Res 7(3):397–403CrossRef

42.

Digard H, Proctor C, Kulasekaran A, Malmqvist U, Richter A (2013) Determination of nicotine absorption from multiple tobacco products and nicotine gum. Nicotine Tob Res 15(1):255–261CrossRef

43.

Perez-Lopez FR, Chedraui P, Cuadros-Lopez JL (2010) Bone mass gain during puberty and adolescence: deconstructing gender characteristics. Curr Med Chem 17(5):453–466CrossRef

44.

Caraballo RS, Giovino GA, Pechacek TF (2004) Self-reported cigarette smoking vs. serum cotinine among US adolescents. Nicotine Tob Res 6(1):19–25CrossRef

45.

Jamieson J (1999) Dealing with baseline differences: two principles and two dilemmas. Int J Psychophysiol 31(2):155–161CrossRef

46.

Pearl, J. (2016). Lord’s paradox revisited–(oh Lord! Kumbaya!). Journal of Causal Inference, 4(2)

Title: The influence of snuff and smoking on bone accretion in late adolescence. The Tromsø study, Fit Futures
Authors: Ole Andreas Nilsen
Nina Emaus
Tore Christoffersen
Anne Winther
Elin Evensen
Gyrd Thrane
Anne-Sofie Furberg
Guri Grimnes
Luai Awad Ahmed
Publication date: 01-12-2021
Publisher: Springer London
Keywords: Osteoporosis
Osteoporosis
Published in: Archives of Osteoporosis / Issue 1/2021
Print ISSN: 1862-3522
Electronic ISSN: 1862-3514
DOI: https://doi.org/10.1007/s11657-021-01003-7

At a glance: The STEP trials

Springer Medicine

The influence of snuff and smoking on bone accretion in late adolescence. The Tromsø study, Fit Futures

Abstract

Summary

Purpose

Methods

Results

Conclusions

At a glance: The STEP trials

Springer Medicine

Abstract

Summary

Purpose

Methods

Results

Conclusions

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