Singh-Manoux and Mika Kivimaki Mark Hamer, Severine Sabia, G. David Batty, Martin J. Shipley
Transcript of Singh-Manoux and Mika Kivimaki Mark Hamer, Severine Sabia, G. David Batty, Martin J. Shipley
Singh-Manoux and Mika KivimakiMark Hamer, Severine Sabia, G. David Batty, Martin J. Shipley, Adam G. Tabàk, Archana
from the Whitehall II Cohort StudyPhysical Activity and Inflammatory Markers Over 10 Years: Follow-Up in Men and Women
Print ISSN: 0009-7322. Online ISSN: 1524-4539 Copyright © 2012 American Heart Association, Inc. All rights reserved.
is published by the American Heart Association, 7272 Greenville Avenue, Dallas, TX 75231Circulation published online August 13, 2012;Circulation.
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DOI: 10.1161/CIRCULATIONAHA.112.103879
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Physical Activity and Inflammatory Markers Over 10 Years:
Follow-Up in Men and Women from the Whitehall II Cohort Study
Running title: Hamer et al.; Physical activity and inflammation
Mark Hamer, PhD1; Severine Sabia, PhD1; G. David Batty, PhD1; Martin J. Shipley, MSc1;
Adam G Tabák, MD, PhD1,2; Archana Singh-Manoux, PhD1,3; Mika Kivimaki, PhD1
1Dept of Epidemiology and Public Health, Univ College London, London, United Kingdom; 21st
Dept of Medicine, Semmelweis Univ Faculty of Medicine, Budapest, Hungary; 3INSERM
U1018, Center for Research in Epidemiology & Population Health, Villejuif, France
Address for Correspondence:
Mark Hamer, PhD
Department of Epidemiology and Public Health
University College London
1-19 Torrington Place
London, WC1E 6BT, United Kingdom
Tel: +44 207 679 5969
Fax: +44 207 916 8542
E-mail: [email protected]
Journal Subject Codes: [8] Epidemiology; [135] Risk Factors
Adam G Tabák, MD, PhD ; Archana Singh Manoux, PhD ; Mika Kivimakaki,i, PhPhD
Dept of Epidemiology and Public Health, Univ College London, London, United Kingdom; 21s
DDeDeptp of f MMMedidicicinene, SeSemmmmellweweis Unin v v FFacaculultyty off Meedidicicine, BuBuBuddapepestst,, Huungngarary;y; 3ININSESERMM
U1018, Cenenenter foforr ReReeseseearchh iin n EpEpEpidemmmiiiolooggyyy & & PoPoPoppupullatioonon Heaaalthhh, VVViilllejuiiif, FrFrannnce
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Abstract:
Background - Inflammatory processes are putative mechanisms underlying the cardio-protective
effects of physical activity. An inverse association between physical activity and inflammation
has been demonstrated but no long-term prospective data are available. We therefore examined
the association between physical activity and inflammatory markers over a 10-year follow-up
period.
Methods and Results - Participants were 4289 men and women (mean age 49.2 years) from the
Whitehall II cohort study. Self-reported physical activity and inflammatory markers (serum high-
sensitivity C-reactive protein [CRP] and interleukin-6 [IL-6]) were measured at baseline (1991)
and follow-up (2002). Forty-nine percent of the participants adhered to standard physical activity
recommendations for cardiovascular health (2.5 hours per week moderate to vigorous physical
activity) across all assessments. Physically active participants at baseline had lower CRP and IL6
levels and this difference remained stable over time. In comparison to participants that rarely
adhered to physical activity guidelines over the 10 years follow-up, the high adherence group
displayed lower logeCRP ( =-0.07, 95% CI, -0.12, -0.02) and logeIL-6 ( =-0.07, 95% CI, -0.10, -
0.03) at follow up after adjustment for a range of covariates. Compared to participants that
remained stable, those that reported an increase in physical activity of at least 2.5 hours/wk
displayed lower loge CRP (B coefficient =-0.05, 95% CI, -0.10, -0.001) and loge IL-6 (B
coefficient =-0.06, 95% CI, -0.09, -0.03) at follow up.
Conclusions - Regular physical activity is associated with lower markers of inflammation over
10 years of follow-up and thus may be important in preventing the pro-inflammatory state seen
with ageing.
Key words: c-reactive protein; epidemiology; exercise; inflammation
ensitivity C-reactive protein [CRP] and interleukin-6 [IL-6]) were measured at basasselele ininee (1(1( 999911)
and follow-up (2002). Forty-nine percent of the participants adhered to standardd pphyhyhysisicacacalll acacactititi ivivityty
ecommendations for cardiovascular health (2.5 hours per week mr oderate to vigorous physical
acacctitivvivityt ) acroroosssss aallllll aassssesesessmsmmenentsts.. PhPhPhysysy icicalallylyy aactctivivee ppaarticcipipipananantst aatt t babab seselilinnne e e haad d lololowewew r r CRCRRP P P ananand d d ILI 6
eeeveveelsl and thihis s diiifffferennnccee rememmaaainened d ststs aababllle ovveverr timememe.. InInn cccomomomppparissosonn to ppaarartiticicipapap ntss s thhhatat raaarelyyy
adhehereredd toto pphyysis caal l acactivivityty guguididelelini es oovever r ththe 1010 yeaearsrs ffolollolow-w upup,, ththe e hiighgh aadhdherenncec ggroroupup
didispsplalayeyedd lolowewerr lologg CRCRPP (( ==-00 0707 9595%% CICI 0-0 1122 -00 0202)) anandd lologg ILIL 6-6 (( ==-00 0707 9595%% CICI 0-0 1100
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The anti-inflammatory effects of exercise are thought to be one of the mechanisms that explain
the well-documented cardio-protective effects of physical activity.1-4 Evidence from
epidemiological studies has demonstrated an inverse association between physical activity and
markers of low grade systemic inflammation.5 However, the majority of existing evidence is
drawn from cross-sectional analyses and few studies have examined the association between
long-term physical activity behaviour and low grade inflammation prospectively. Cross-sectional
data make it difficult to discount reverse causation effects. For example, some evidence suggests
low grade inflammation is a marker of sarcopenia,6 thus functional limitations might explain
associations between systemic inflammation and low activity in ageing populations.7 Tracking
low-grade inflammation is particularly relevant in an ageing population, as inflammatory
markers gradually rise with increasing age and this pro-inflammatory status underlies biological
mechanisms responsible for cardiovascular disease (CVD) and other age-related diseases.8-10
Since the majority of health benefits from exercise are established through chronic
training adaptations, it is difficult to draw firm conclusions from short-term exercise trials often
lasting less than 6 months. Indeed, this might partly explain the equivocal nature of clinical trial
data on exercise and inflammatory markers.11 Thus, in the present study we examined the
association between physical activity and inflammatory markers over a 10-year follow-up period
using a well characterised population based cohort study.
Methods
Participants
Participants were drawn from the Whitehall II population based cohort.12 The Whitehall II study
is an on-going prospective cohort study that consists of 10,308 participants (6,895 men and 3,413
women aged 35 to 55) recruited from the British civil service in 1985 in order to investigate
ow-grade inflammation is particularly relevant in an ageing population, as inflamammmamm totooryryry
markers gradually rise with increasing age and this pro-inflammatory status underlies biological
memechchchanananiisismsmsm rrrespopoponnsnsible for cardiovascular diseeasasasee (CVD) and otthehh r agaggee-e-related diseases.8-10
Since ththheee mmamajojojoriitytyty ooof f f hehhealalththth bbeenneeefitss frrromm eexxercrcciisise e aarare e esesstaaablblmm isisheheh dd ththhroroougughh h chchchrorooniniicc
rraiaiainininingngng aadadadaptptp atatiioonnsns,, iitt iiss s did ffffficici ulululttt tototo ddrraraw w w fififirmrmm ccoononcccluususioioonsnsns ffrororom mm shshhororo t-t--teeermrm eexxexercrccisisiseee trrriaalslsl ooffteenen
asting less tthahaan n n 6 6 6 momom ntntnthshh .. InInIndededeededed,, thththisss mmmigigighththt pppararartltltlyyy eeexpxpplalalaininin ttthehehe eeeququuivivivocococalalal nnnaatuuurerere oooff f clclc inical trial
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social and occupational influences on CVD risk. The baseline medical examination (Phase 1)
took place during 1985/88, and subsequent phases have alternated between questionnaire alone
(Phases 2, 4, 6 and 8) and phases including both a medical examination and a questionnaire
(Phases 1, 3, 5, 7 and 9). For the purposes of the present study, phase 3 (1991/93) was regarded
as the baseline when inflammatory markers were first assessed and phase 7 (2002/04) as the
follow up. The mean follow-up time between phases 3 and 7 was 11.3 years (range, 9.5–12.9
years). Participants gave full informed written consent to participate in the study and ethical
approval was obtained from the University College London Hospital committee on the Ethics of
Human Research.
Physical activity assessment
Physical activity was assessed at phases 3, 5 (1997/99), and 7 using a self-reported questionnaire.
At phase 3, the physical activity assessment consisted of 3 questions about duration and
frequency per week spent at light, moderate and vigorous intensity physical activity. At phases 5
and 7 the physical activity questions consisted of 20 items on frequency and duration of
participation in walking, cycling, sports, gardening, housework, and home maintenance.13
Frequency and duration of each activity were combined to compute hours per week of moderate
to vigorous physical activity. The 20-item self-reported physical activity questionnaire is a
modified version of the previously validated Minnesota leisure-time physical activity
questionnaire.14 In addition, the self-reported physical activity measure has demonstrated
predictive validity for mortality in the Whitehall II study.15 Although assessed slightly
differently, physical activity (moderate-vigorous hrs/wk) measured at phase 3 was correlated
with physical activity measured at phases 5 (Spearman’s r=0.41, p<0.001) and 7 (r=0.36,
p<0.001). Similar correlations were observed between physical activity at phases 5 and 7
Physical activity assessment
Physical activity was assessed at phases 3, 5 (1997/99), and 7 using a self-reported questionnaire
AtAt ppphahahassese 333,, thththe phphphyysysical activity assessment connnssisistted of 3 questiionono s aabobobouut duration and
ffrreqqqueu ncy per r weweeeekk sspppentntnt aaat t lililigghght,t, mmmododdeerratee annnd vvvigggorououous s ininntteensnsiityyy phphhyyysiicaal l l aacactitivivivitytyy.. AAtA ppphahahaseseses s 5
anndd d 777 ththt ee phphphyysysicicaal aactctiviviitityy quuuesestititionononsss cocoonsnsnsisisisttted dd ofofof 2000 itttememmss s ononn fffrereeququuenene cccy aandndd dddururu atatatioioon ooof
participation n ininin wwalalalkikik ngngng, , cycyyclclclining,g,g sspopoportttsss,, , gagagardrdrdenenenininng,g,g hhhouuusesesewowoworkrkrk,,, ananandd d hohohomememe mmmaiaiaintntntenenenananancec .131313
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(r=0.51, p<0.001) when assessed with an identical questionnaire.
Clinical assessment and Inflammatory markers
The procedures for the clinical examination have been described elsewhere.12 Briefly,
measurements included height, weight, waist and hip circumference, blood pressure, and a
fasting blood sample taken from the antecubital fossa. Fasting serum was collected between 0800
and 1300 h and was stored at 70 C. Samples from phases 3 and 7 were analyzed at the same
time. The inflammatory marker C-reactive protein (CRP) was measured using a high-sensitivity
immunonephelometric assay in a BN ProSpec nephelometer (Dade Behring, Milton Keynes,
UK). Interleukin-6 (IL-6) was measured using a high-sensitivity ELISA (R&D Systems, Oxford,
UK). Values lower than the detection limit (0.15 mg/l for CRP and 0.08 pg/ml for IL-6) were
assigned a value equal to half the detection limit. To measure short-term biological variation and
laboratory error, a repeated sample was taken from a subset of 150 participants for CRP and 241
for IL-6 at phase 3 [average elapse time between samples 32 (SD=10.5) days], and 533 for CRP
and 329 for IL-6 at phase 7 (average elapse time 24 (SD=11.0) days]. Intra- and inter-assay
coefficients of variation were 4.7% and 8.3% for CRP, and 7.5% and 8.9% for IL-6 at phases 3
and 7, respectively. A questionnaire was completed regarding age, civil service employment
grade (a measure of socioeconomic status, SES), smoking habits, health status and hormone
replace therapy (HRT, women only).
Statistical analysis
The inflammatory markers displayed a skewed distribution, and normality was obtained after
natural logarithmic (loge) transformation. Participants were categorised according to whether
they adhered to the physical activity guidelines (at least 2.5 hr per week moderate to vigorous
physical activity) that are widely used and have been quantitatively validated for cardiovascular
UK). Values lower than the detection limit (0.15 mg/l for CRP and 0.08 pg/ml ffooror IIL-L-L 6)6)6) wwwererere e
assigned a value equal to half the detection limit. To measure short-term biological variation and
aaboboorararatototoryryy eeerrrrror, , aa a rerepeated sample was taken frromomo a subset of 150500 parartititiccicipants for CRP and 241
ffoor ILIL-6 at phasaseee 33 [aavvverraragegege eeelalalapspse ee titit mmeme betwwweeeen sasaampmppleleess 3332 ((SDSDD==1=10.0 5)55 ddayayys]s]s],, anannd d d 535353333 fofofor r CRCRCRP
anndd d 32323299 foforr r ILILIL-6-6 aat t t phphhasasse e 7 7 (a(a(aveveerararagegege eelalal pspspsee e timmeme 222444 (S(SSD=D=D=11111.000))) ddadaysysys].].] IIIntnttrara-- anannd d ininnteteter--aaasssasay y
coefficients ooff f vavav riririatatatioioon n n weweererere 4.7.7.7% %% anaa d d d 8.8.8 3%3%3% fffororor CCCRPRPR , ananand d d 7.77 5%5%5% aandndnd 888.9.9.9% % % fofor r r ILILIL-6-66 aaat t phases 3
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outcomes.16,17 In order to examine associations between baseline physical activity and change in
inflammatory markers between phases 3 to 7 we adopted a linear mixed models approach and
fitted the intercept as a random effect.18 The model included terms for baseline physical activity,
time (phase 3 corresponds to time 0, phase 7 to time 1, so that coefficients associated with time
correspond to a 10yr change), and an interaction term between physical activity and time to
estimate the association between baseline physical activity and change in inflammatory markers
over the follow-up. This model also included covariates that were associated with both physical
activity and inflammatory markers. In order to examine the effects of long-term physical activity
exposure over the three assessments participants were categorised as ‘Rarely’ meeting guideline
(once or less through follow-up); ‘Sometimes’ (on two phases); ‘Always’ (on all three follow-up
phases). We fitted general linear models to examine the association between long term physical
activity exposure (number of times meeting the guideline over follow-up) and inflammatory
markers at follow up, adjusting for age, gender, smoking, employment grade, body mass index
(BMI), and chronic illness. In separate sensitivity analyses we adjusted for waist to hip ratio
instead of BMI, and also modelled BMI change. We also investigated associations between
changes in physical activity (calculated as the difference in hours/wk of moderate to vigorous
activity between phases 5 and 7) and inflammatory markers using general linear models. Lastly,
we used linear mixed models to examine associations between baseline inflammation
(categorised as CRP <1mg/l; 1 to < 3 mg/l; 3mg/l) and change in moderate to vigorous
physical activity (hrs/wk) between phases 3 to 7, fitting the intercept as a random effect term and
an interaction term between CRP category and time. All analyses were conducted using SPSS
version 20 (SPSS, Chicago, IL) using two-sided tests with a significance level p<0.05.
once or less through follow-up); ‘Sometimes’ (on two phases); ‘Always’ (on allll thrhrreee fffololollololow-w-w upp
phases). We fitted general linear models to examine the association between long term physical
acctitiivivivitytyty eexpxpxpososurre e e ((n(number of times meeting the gugug iiddeline over fololllol w-w-upupup) ) and inflammatory
mmarrkrkers at folllolowww upup,, adaddjujujusststinininggg fofoorr r aagageee, ggennddeeer, smmmookininngg,g, eempmmploloymmmenentt t ggrradadde,e, bbododdy yy mamamassss iiinddndexexx
BBBMIMIMI)),), aandndd ccchhrhrononnicicc iilllllneneessss. InInn sseeepapaparraratetee ssenenensisisitivivivitytyy aannalylylysesesess s wewee aadddjususustetet ddd ffofor r wawawaisisi t t tototo hhipipp rratatioioo
nstead of BMIMIMI,, , anannd d d alallsosoo mmmodododellleleledd d BMBMBMII I chchchananangegege. WeWeWe aalssso oo inininvevevestststigigigatattededed aaassssssococociaiatitit ononons s bebebetwt een
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Results
At baseline 7366 participants had available data on all variables although after excluding
participants with missing data through follow-up the final analytic sample comprised 4289
participants (3092 men and 1197 women). Participants excluded were slightly older (50.1 vs.
49.2 yrs, p<0.001), less physically active (3.3 vs. 3.6 hrs/wk moderate to vigorous physical
activity, p=0.003), and had higher baseline loge CRP values (0.87 vs. 0.75, p<0.001) compared
with those included. However, these absolute differences in characteristics between the groups
were trivial, only attaining statistical significance owing to the large sample size. Approximately
half the sample (49%) adhered to the physical activity recommendation (2.5 hrs per week
moderate to vigorous physical activity) across all assessments (50% at phase 3 [baseline]; 83.7%
at phase 5; 83.3% at phase 7). Participants that ‘always’ met the physical activity guidelines were
more likely to be men, from higher employment grades, and had lower BMI (Table 1).
Baseline physical activity and change in inflammatory markers
Meeting the physical activity guideline at baseline was inversely associated with baseline loge
CRP (coefficient = -0.04, 95% CI, -0.07, -0.01, p=0.007) and loge IL-6 (coefficient = -0.04, 95%
CI, -0.06, -0.02, p=0.001) after adjustments for age, gender, smoking, employment grade, BMI,
and chronic illness (Table 2). On average, there was an increase in both inflammatory markers
from baseline to follow-up: loge CRP increased from 0.75 to 0.94 (p<0.001) and loge IL-6 from
0.93 to 1.08 (p<0.001), corresponding to a change of 0.44 mg/l (21%) in CRP and 0.41 pg/ml
(16%) in IL-6 over 10 years. There was no statistically significant association between baseline
physical activity and change in loge CRP (p=0.10) or loge IL-6 (p=0.39) over follow-up (Table
2), suggesting that the difference in inflammation levels persisted but did not increase across
time (Figure 1).
moderate to vigorous physical activity) across all assessments (50% at phase 3 [[bbabaseseeliiinenne];];]; 88833.3.77%
at phase 5; 83.3% at phase 7). Participants that ‘always’ met the physical activity guidelines were
momorerere lllikikikelelelyy y tototo bee e mmemen, from higher employmenttt gggrraades, and had lllowo ererr BBBMIM (m Table 1).
BBasseseline physisiccaall acactitit viviittyty aaandndnd cchahahangngge iin iinfnfnflammmmmmatororory y mamamarkrkerrrs
MeMeeetetetininingg g ththhe ee phpphyysysicccalal aactcttivivity y y guguuidididelelelinineee atatat bbbaasa elelelinineee wawawass inininvveverssselele yy y asasassosos ccciaatatededd wwititi h h bababasellilinenee lloogogee
CRP (coefficcieieientntn == --0.0..04044, 959595% %% CICICI, , -0-00.0007,7,7 --0.0.0.010101, , p=p=p 0.0.0.00007)7)7) aaandndnd lllogogoge IIIL-L-L-6 6 6 (c(c(coeoeoefffficicicieieientntnt == -0.04, 95%%%
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Habitual physical activity over 10 years and inflammatory markers at follow up
In comparison to participants that rarely adhered to physical activity guidelines through follow
up, the high adherence group displayed lower loge CRP (B coefficient=-0.07, 95% CI, -0.12, -
0.02) and loge IL-6 (B coefficient =-0.07, 95% CI, -0.10, -0.03) at follow up after adjustment for
age, gender, smoking, employment grade, BMI, and chronic illness (Table 3). These coefficients
corresponded to a fully adjusted difference of 0.18 mg/l in CRP and 0.20 pg/ml in IL-6 between
individuals who adhered consistently compared to those that did not adhere to physical activity
guidelines over 10 years. When we adjusted for waist circumference as a marker of central
adiposity (instead of BMI) the effect estimate was slightly attenuated for loge CRP (B
coefficient=-0.04, 95% CI, -0.10, 0.01) but changed little for loge IL-6 (B coefficient =-0.06,
95% CI, -0.09, -0.02). Participants that were consistently physically active over follow up gained
less weight compared to those rarely active (average BMI increase, 1.4 ± 1.8kg/m2 vs. 1.6 ±
2.2kg/m2, p=0.04). However, when we adjusted for change in BMI during follow-up (instead of
BMI at baseline) this did not alter the association between physical activity and inflammatory
markers.
We examined the associations for change in physical activity (Table 4). In order to retain
consistency we calculated changes in activity between phases 5 and 7 when the same
questionnaire was used. Compared to participants that remained stable, those that reported an
increase in physical activity of at least 2.5 hrs/wk displayed lower loge CRP (B coefficient =-
0.05, 95% CI, -0.10, -0.001) and loge IL-6 (B coefficient =-0.06, 95% CI, -0.09, -0.03) at follow
up after adjustment for age, gender, hours/week of moderate to vigorous physical activity at
phase 5, smoking, employment grade, BMI, and chronic illness. There was no difference in
inflammatory markers between participants that reported a reduction in physical activity
coefficient=-0.04, 95% CI, -0.10, 0.01) but changed little for loge IL-6 (B coefficicciieientntn ===-0-00.0.006,6,6,
95% CI, -0.09, -0.02). Participants that were consistently physically active over follow up gained
eesssss wwweieieighghghtt t cocoompmppaararede to those rarely active (averereragagagee BMI increasesee, 1..4 44 ±±± 1.8kg/m2 vs. 1.6 ±
22..2kkkg/g m2, p=0.0 040404).. HHowowowevevererer, wwhwhenenen wweee aaadjuuststeeed ffororor chhananngegee inn n BBMMI I dudurirr nngng fffololollolow-w-w-upupp (((inini stststeaeaad d oof
BMBMMI I atatat bbasasseleleliinine)e)) thhihiss dididd d nnot tt alallteteterrr thththe e asasa sososociciciatttioioionn bebeetwwweeeeennn phphphysysy iiccalalal aaactcttivvvitity y ananand d d ininnflflflammmmmamatotorryry
markers.
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compared with those remaining stable.
Sensitivity analyses
In order to account for non-specific inflammatory responses we re-ran the analysis after
removing 823 participants who had reported acute infections such as cold or influenza 2 weeks
prior to the phase 7 clinical assessment. This did not, however, change the results; for example,
compared with participants rarely meeting physical activity guidelines, those that always met the
guidelines had significantly lower loge CRP at follow-up (fully adjusted B coefficient = -0.06,
95% CI, -0.11, -0.005). We ran additional analyses in order to account for potential effects of
HRT in women. 586 women never used HRT, 211 constantly used HRT, 26 stopped, and 336
started HRT through follow-up (n=38 missing data). In comparison to the women that never used
HRT, only those that started using HRT through follow up displayed elevated loge CRP at follow
up (age adjusted coefficient = 0.11, 95% CI, 0.03, 0.19). We re-ran the analyses for physical
activity and inflammatory markers in women making additional adjustments for HRT use (as
categorised above; never/ constant/ stopped/ started). The results still showed that in comparison
to women that rarely adhered to physical activity guidelines, the high adherence group displayed
lower loge CRP (fully adjusted B coefficient=-0.10, 95% CI, -0.20, -0.01, p=0.04) and loge IL-6
(B coefficient =-0.07, 95% CI, -0.13, -0.01, p=0.02) at follow up.
Association of basal inflammatory markers with physical activity change
We also examined the association between baseline inflammatory markers and change in
moderate to vigorous physical activity from phase 3 to phase 7 using linear mixed models.
Participants with CRP 3mg/l at baseline demonstrated decreased moderate to vigorous physical
activity (hrs/wk) at phase 7 (estimate for CRP * time interaction = -1.14, 95% CI, -0.35, -1.92;
p=0.004) compared to those with CRP<1mg/l, after adjustments for age, gender, smoking,
tarted HRT through follow-up (n=38 missing data). In comparison to the womenenn tthahah tt t nenenevevever r r uused
HRT, only those that started using HRT through follow up displayed elevated loge CRP at follow
upup (((agagageee adadadjujujuststs edd cccooeoefficient = 0.11, 95% CI, 0.00033,3, 000.19). We re-raraan n thhe ee aananalyses for physical
acctiivvity and infnfflalalammmmmataatororry y mamam rkrrkererrsss inini wwwooomeenn makkkinnng aaaddddditittioionanall addjujuststtmementnttss ffofor r HRHRHRTT usussee e (aa(as
caatetetegogogoririr sesedd d abababovovve;;; nneveveerr/ / coconnsn tatatantntnt/ / / ststoopoppepeped/d/d/ sstatatartrtededed).).) TTThehehe rrresessululu tstss sstttttt ililill l ssshoowoweeded ttthahatt t ininin ccomomompaparrrissoon
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employment grade, BMI, and chronic illness.
Discussion
Given that the majority of existing data on physical activity and markers of systemic
inflammation is cross-sectional, the aim of this study was to explore the longitudinal association
between physical activity and inflammatory markers over a 10-year follow-up period. The main
findings show that physically active participants at baseline had lower CRP and IL-6 levels and
this difference remained stable over time. Secondly, maintenance of physical activity over the 10
years follow-up period was associated with lower levels of both inflammatory markers at follow-
up. An increase in physical activity was also associated with lower levels of both inflammatory
markers at follow up. Crucially, the associations observed between physical activity and
inflammatory markers were independent of adiposity, which is an important confounder of the
association between physical activity and inflammatory markers as physically active participants
tend to have lower levels of adiposity, and adipose tissue is a key production site for several
inflammatory markers.19 Previous data from the Whitehall II study have demonstrated that
increases in BMI and waist circumference over time were associated with higher levels of
inflammatory markers at follow up,20 although the present findings were independent of changes
in body composition. Another important finding showed that basal systemic inflammation was
associated with reduction in physical activity over follow up, after adjusting for confounders
such as BMI and chronic illness. Given that inflammatory processes are thought to be involved
in sarcopenia and functional decline,6,7 this explains why systemic inflammation may result in
decreased activity in ageing populations.
Physical activity, inflammation and health are linked together in a complex fashion.
Cytokines are secreted transiently in large doses by several metabolically active tissues during
markers at follow up. Crucially, the associations observed between physical activivvitity yy ananndd d
nflammatory markers were independent of adiposity, which is an important confounder of the
asssosoociciciatatatioioionn n bebebetwweeeeeen n physical activity and inflammmmmmaaatory markers asasa phyhyyssisicac lly active participants
eenddd to have lowowerrr levevvellsss ofofof aaadiddipopoosisisittyty,, aannd aaadiiiposse ttissssuuee iisss aa kekeyy prprododducucuctiiononon ssitite e fofofor r r seseeveveerarall l
nnflflflamamammamam totooryryry mmaararkkekersrss.199 PPreeviviv ououousss dadad tataa fffrororommm thhhe e e WhWhWhitehehehaaallllll III ststs uududy yy hahah vvve ddememmonononststtrararattted d thhhatat
ncreases in BBBMIMIM aaandndn wwwaia ststst cccirii cucucumfmfmferere enenncecee ooovevever r r titiimememe wwererereee asasassosoociciciata ededed wwwititithh h hihih ghghhererer llevevevelee s of
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exercise; namely from the muscle during contraction and adipose tissue via exercise-related
mechanisms. Paradoxically, regular (chronic) exercise training has been consistently associated
with lower levels of systemic inflammatory markers5 and reduced adipose tissue inflammation.21
The expression of exercise-regulated muscle genes, such as the transcriptional co-activator
PGC1 , is thought to promote anti-inflammatory effects through a transient release of
cytokines,22 and possibly explains some of the systemic and beneficial effects of exercise in non-
muscle tissue.21-25 In contrast, chronically elevated levels of low grade systemic inflammation
have been linked to the development of many diseases associated with inflammation including
CVD, sarcopenia, neurodegeneration and depression.6-10, 26, 27 Thus, the transient fluctuations of
cytokines following exercise might contribute to the beneficial effects of exercise on organs
other than muscle in a hormone-like fashion, whereas chronic, low grade elevation of many of
these same molecules is almost certainly pro-inflammatory and detrimental.
A notable strength of this study is the repeated serial measures taken over a 10-year
follow-up period in a well characterised cohort. This allowed us to track changes in physical
activity, inflammatory markers and other important clinical variables. Self-reported measures of
physical activity are prone to reporting bias although the questionnaire used in the present study
is well validated and has demonstrated convergent validity in predicting mortality in the
Whitehall II study.15 In addition, among a sub-cohort of 394 Whitehall II participants, we
recently demonstrated that self-reported physical activity was associated with objectively
(accelerometry) assessed activity at 10-year follow-up across various activity categories.28
Although there was only modest correlation between physical activity measures at different
phases of data collection, we did observe an upward trend in physical activity. This might be
explained by the fact many participants from Whitehall II were in the transition to retirement
cytokines following exercise might contribute to the beneficial effects of exercisseee ononon ooorgrgrgananansss
other than muscle in a hormone-like fashion, whereas chronic, low grade elevation of many of
hhesessee e sasasamememe mmmolececcuululees is almost certainly pro-inffflalalammmmatory and dedeetrimmenenentat l.
A notaablblblee e ssstrerengngngththth ooof f f thththisis ssstutuudydyy iis thhee rrrepeeeaatted sseereriaiaal memeaasasurureses taakkenenn ooovever r a 101010-y-y- eeaear r
foollllllowowow-u-uppp pepepeririododd inn n aa weweellll chhahararaactctcteeerirriseseed d cococohhhortrtrt.. TThThiisis aaalllowowowededed uuuss tooo tttrarar cckck cchahaangngngeses iiinn n phphhysssicicaall
activity, inflamammmamamatototoryryry mmmarrrkekekersrr aaandndn ooothhhererer iiimpmpmpororortataantntn clclc innnicicicalalal vvvararariaiaiablbllesese .. SeSeSelflflf-r-rrepeppororortetetedd d memm asures off f
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12
during this period. This is consistent with recent data from the GAZEL cohort 4 years before and
4 years after retirement showing that leisure-time physical activity increased by 36% in men and
61% in women during the transition to retirement.29 Our findings on the association between
baseline inflammatory markers and change in physical activity over follow up should be
interpreted with caution as we were unable to account for presence of sarcopenia. Nevertheless,
the analyses were adjusted for chronic illness that incorporates factors such as functional
limitations and history of CVD.
In summary, the results show that physically active participants maintain lower levels of
inflammatory markers over a 10 year period. Thus, physical activity may be important in
preventing the pro-inflammatory state seen with ageing.
Acknowledgements: We thank all participating civil service departments and their welfare
personnel, and establishment officers; the Occupational Health and Safety Agency; the Council
of Civil Service Unions; all participating civil servants in the Whitehall II study; all members of
the Whitehall II study team. The Whitehall II Study team comprises research scientists,
statisticians, study coordinators, nurses, data managers, administrative assistants and data entry
staff, who make the study possible.
Funding Sources: The Whitehall II study has been supported by grants from the Medical
Research Council; British Heart Foundation; Health and Safety Executive; Department of
Health; National Heart Lung and Blood Institute (R01HL36310), US, NIH: National Institute on
Aging (R01AG013196; R01AG034454), US, NIH; Agency for Health Care Policy Research
(HS06516); and the John D and Catherine T MacArthur Foundation Research Networks on
Successful Midlife Development and Socio-economic Status and Health. MH and MJS are
supported by the British Heart Foundation (RE/10/005/28296) and (RG/07/008/23674); MK is
supported by the EU New OSH ERA research programme and the Academy of Finland; GDB is
a Wellcome Trust Research Fellow; SS is supported by the NIH (grant R01AG034454); AS-M is
preventing the pro-inflammatory state seen with ageing. y
AcAcknknknowowowleleledgdgdgememenenentst : We thank all participatinggg cccivvvil service depapaartmemeentntntss and their welfare
ppeersssono nel, aandnd eeesstababa lililishshmemmentntnt ooofffffficicicererers;s;s; ttheheh OOOcccccuupapaatiioonalalal HHHeaeae ltltl h h anana d d d SaSaSaffefetty AAAgegegencncncy;y;y; tthehehe CCCouououncncciil uu
ofoff CCCivi il Servivice UUnnionnns;; allll ppaaarticicipppataa iinnggg civvvill serrvvaanantstss iiin nn thththee Whhiittehallll IIIII ssstuuudydy; aalall memeemmmberrrs of
hhe WhWhWhitititehehehalalll IIIII ssstututudydydy ttteaeaeamm. TTThehehe WWWhihitetehahahallllll IIIIII StStS udududyyy tetet amamam ccomomomprprisisiseseses rrreeett seseseaararchchh ssscicicienenentitiststtsss,
tatisticians,, ssstututudydydy cccoooooordrddinnnatata oroo s,s,, nnnururrsess s,s,s, dddatatata a a mamam nananagegegersr ,, adadadmimiminininistststraratititiveveve aaassssssiiiststs ananntststs aaandndnd ddata entry
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supported by a ‘EURYI’ award from the European Science Foundation. The funders played no
role in the design and conduct of the study; collection, management, analysis, and interpretation
of the data; and preparation, review, or approval of the manuscript. Dr Hamer had full access to
the data and takes responsibility for the integrity of the data and accuracy of the data analysis.
Conflict of Interest Disclosures: None.
References:
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2288. HHamer M, KKKivivimimakaka i i MM,M, SSSteteteptptoeoeoe AA.. LLLongggitttudinananal papaattttterernnsns iin n phphhysysicicicall aactcttivivivitity y anana d d d sseedededentnttarararyy bebeehahaaviour frromom mmmiiid-liifeee to eeearrrlyy olddd aagegege: A suuub-stutudydy ooof f f thththee WhWhWhitteehallll IIII ccohohohorort. JJJ EEpEpiiddeeemioool CoCoommmmmmununu itity y y HeHHeaallthhh.. 22001012 2 2 [e[ -p-ppububub aaaheheheadadd oooff f prprprinnnt]t]t]
29. Sjösten N,N,N, KKKivivvimimimäkäkäki ii M,M,M, SSSininnghghgh-M-MMannnouououx x x A,A,A FFFeeerrrrrrieiee JE,E,E, GGGololo dbdbdberere g g M,M,M, ZZZininins s s M,M,M, PPPenenentttttii J, WeWeststererlulundnd HH VaVahthtereraa JJ CChahangngee iinn phphysysicicalal aactctivivitityy anandd weweigightht iinn rerelalatitionon ttoo rretetirirememenent:t: tthehe
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Table 1. Descriptive characteristics of the sample at baseline in relation to habitual physical activity through follow up (n= 4289).
Variable Meeting physical activity guidelines through follow up†
Rarely (n=681) Sometimes (n=1503) Always (n=2105) Age (yrs) 48.7 5.7 49.4 5.9 49.1 6.0 % men 56.8 63.9 82.9 % low grade employees
21.6 12.2 6.5
% smokers 13.2 10.6 10.1 % Chronic illness 35.8 35.2 29.9 Average MVPA (hrs/wk)
1.1 1.9 1.3 1.5 6.0 3.9
Body Mass Index (kg/m2)
25.3 ± 3.9 25.1 ± 3.6 24.9 ± 3.2
CRP‡ (mg/L) 2.29 ± 1.90 2.16 ± 1.81 2.05 ± 1.74 IL-6‡ (pg/mL) 2.70 ± 1.55 2.61 ± 1.47 2.45 ± 1.42 † Meeting physical activity guidelines (at least 2.5 hrs moderate to vigorous physical activity [MVPA] per week); ‘Rarely’ includes meeting guideline once or less through follow-up; ‘sometimes’ on two phases; ‘always’ on all three follow-up phases. ‡ Geometric mean (± SD)
Table 2. Linear mixed models to examine the association between meeting physical activity guidelines at baseline on inflammatory markers over phases 3 to 7.
Loge C-reactive protein Loge interleukin-6
Estimate (95% CI) Estimate (95% CI)
Meeting physical activity guidelines at baseline
Model 1 Model 2 Model 1 Model 2
No Reference Reference Reference Reference
Yes -0.06 (-0.09, -0.04) -0.04 (-0.07, -0.01) -0.05 (-0.07, -0.04) -0.04 (-0.06, -0.02)
Interaction term: PA * time 0.03 (-0.01, 0.06) 0.03 (-0.01, 0.06) 0.01 (-0.01, 0.03) 0.01 (-0.01, 0.03) Model 1; adjusted for age, gender. Model 2; adjusted for age, gender, smoking, employment grade, BMI, chronic illness. Physical activity (PA) by time interaction term calculated from meeting the PA recommendation (no=0, yes=1) and time (phase 3 corresponds to time 0, phase 7 to time 1).
Body Mass Index kg/m2)
25.3 ± 3.9 25.1 ± 3.6 244.999 ±± 33.2.2
CRP‡ (mg/L) 2.29 ± 1.90 2.16 ± 1.81 2.05 ± 1.74L-6‡ (pg/mL) 2.70 ± 1.55 2.61 ± 1.47 2.45 ± 1.42
† MeMeMeetettinining phphphysysy ici all aaacctctivi ity guidelines (at least 2.5 hrs mmodoo eeerate to vigorous s php ysysicicicalalal activity [MVPA] per week)RRRarareelely’’ incluludededes memeetetining g g gugug ididelelinne e ononcece oor r lelessss tthrhrououghgh ffooollow-w-upupp;; ; ‘sommmeetetiimmeses’’ ononn twowo ppphahaseses;s; ‘‘alalwawaysysy ’ onon alhhhreee e follow-up phphhasasa ess. Geeeometric mean ((±± SSD)
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Table 3. Adjusted coefficients (95% CI) for habitual physical activity over 10 years on inflammatory markers at follow up (n= 4289).
Loge C-reactive protein Loge interleukin-6 Meeting physical activity guidelines‡
Model 1 (95% CI)
Model 2 (95% CI)
Model 1 (95% CI)
Model 2 (95% CI)
Rarely (n=681) Reference Reference Reference Reference
Sometimes (n=1503)
-0.10 (-0.16, -0.04) -0.08 (-0.13, -0.02) -0.06 (-0.10, -0.03) (-0.08, -0.01)
Always (n=2105) -0.11 (-0.17, -0.05) -0.07 (-0.12, -0.02) -0.09 (-0.12, -0.06) -0.07 (-0.10, -0.03)
p-trend 0.001 0.02 0.001 0.001 ‡ Meeting physical activity guidelines (at least 2.5 hrs MVPA per week); ‘Rarely’ includes meeting guideline once or less through follow-up; ‘sometimes’ on two phases; ‘always’ on all three follow-up phases. Model 1; adjusted for age, gender. Model 2; adjusted for age, gender, smoking, employment grade, BMI, chronic illness.
Table 4. Adjusted coefficients (95% CI) for physical activity change on inflammatory markers at follow up.
Loge C-reactive protein Loge interleukin-6 Physical activity change‡
Model 1 (95% CI)
Model 2 (95% CI)
Model 1 (95% CI)
Model 2 (95% CI)
Stable (n=989) Reference Reference Reference Reference
Decrease (n=1636) -0.04 (-0.09, 0.02) -0.02 (-0.07, 0.03) -0.02 (-0.05, 0.01) -0.01 (-0.04, 0.02)
Increase (n=1664) -0.06 (-0.12, -0.01) -0.05 (-0.10, -0.001) -0.08 (-0.10, -0.04) -0.06 (-0.09, -0.03)
p-trend 0.04 0.12 <0.001 <0.001 ‡ Physical activity change calculated from phases 5 through 7. A decrease/increase represents a change of at least 2.5 hrs/wk of moderate to vigorous physical activity. Model 1; adjusted for age, gender, and hrs/wk of moderate to vigorous physical activity at phase 5. Model 2; adjusted for age, gender, hrs/wk of moderate to vigorous physical activity at phase 5, smoking, employment grade, BMI, chronic illness.
Figure Legend:
Figure 1. The association between physical activity at baseline in relation to change in C-
reactive protein (upper panel) and interleukin-6 (lower panel) over 10 years. Solid and dashed
lines represent participants that do not and do adhere to physical activity guidelines, respectively.
Participants are 4289 men and women from the Whitehall II cohort assessed during 1991 – 2002.
The geometric means are adjusted for age, sex, smoking, employment grade, BMI, chronic
illness.
Table 4. Adjusted coefficients (95% CI) for physical activity change on inflammamamatototoryryry mmmarararkekekerrrs afollow up.
Loge C-reactive protein Loge interleukin-6 Physical activity chanangegege‡‡‡
Model 1(((959595%% CICICI) ) )
Modeded l 22(((9595%%% CCCI)
MoMM dedelll 111(((959595%% CICIC )
Model 2(((959595%%% CICICI) )
Stabbblel (n=989) RRReffefererreenncece RReeefereenencce RRefeferrenenccee RReeefeererenenccce
DeDeecrcreeae sese (n=n=16161636366)) -0-0..044 (-(-0.0.09099,,, 0.0.020202) -) -0.0 0022 (((-00.0.007,,, 00.0.0033)3) ---0.0 002 ((-00.0. 55, 00.0.001)1)) -000.0001 ((-00.0.04,4, 0.0.02)
ncrreaeasse ((n=n=166464) ) -0-0.06 (-(-0.1212, , -00.001)) -0-0.005 5 (-(-00.101 , , -00 0.00101) ) -0-0.08 8 (-(-0.0 1010, , -00.04)4) -0.066 ((-0.009,9, -0.0303
p-p trend 000.04040 000 1.122 <0<0<0 0.00010101 <0.001
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by guest on August 16, 2012http://circ.ahajournals.org/Downloaded from