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Influence of smoking on salivary interleukin-8 levels in 

chronic periodontitis 
 

Haween T. Nanakaly (1), Aveen E. Ismail (2), Daldar A. Othmn (3) 

 

ABSTRACTS 
Background: smoking is the major environmental risk factor that has been associated with the pathogenesis and progression of 

periodontal diseases. Interleukin-8 (IL-8), has been associated with the immunopathology of periodontitis. 

Objectives: To determine the influence of smoking on salivary Interleukin-8 level from smokers and non-smokers with 

periodontitis and periodontally healthy control subjects.   

Materials and Methods: Un-stimulated saliva samples were collected of 90 participants: 30 smokers and 30 non-smokers with 

chronic periodontitis, as well as 30 periodontally healthy control subjects. The clinical parameters such as the pocket depth, 

clinical attachment loss, plaque index, and gingival index were measured. IL-8 level in the saliva was measured by Enzyme 

Linked Immunosorbent Assay (ELISA) kit.  

Results: It was found that the mean value of salivary IL-8 levels was significantly higher in smokers (461.76 ± 329.66 ng/L) than 

in non-smokers periodontitis (257.83 ± 247.19 ng/L) and the controls (96.55 ± 62.35 ng/L) (p < 0.001). Moreover, salivary IL-8 

levels were significantly higher in smokers compared with non-smokers periodontitis (p< 0.001).  

Conclusion: Smoking subjects showed increased level of salivary IL-8 and a worse periodontal condition than non-smoking 

subjects. Our results suggest that smoking alters an immune response which may contribute to an increased susceptibility to 

periodontal disease among smokers 

Keywords: Smoking; Chronic periodontitis; Saliva; Interleukine-8. (Received: 15/8/2018; Accepted: 30/9/2018) 

 
INTRODUCTION 
Saliva is a fluid, which provides a primary growth 

environment for oral flora of the oral cavity. 

Salivary secretions are protected in nature because 

they preserve the oral tissues in a physiological 

state. As the physic-chemical properties are 

changed, it affects the microorganisms which grow 

in the mouth. Therefore, the protective effect of 

saliva may be accomplished by means of secretion 

rate, buffering capacity, phosphate and calcium 

concentration (biochemical substances, 

antibacterial components, and different 

antioxidants).(1)  Saliva with and without 

stimulation is readily accessible via a totally non-

invasive collection method, which contains locally 

produced microbial and host response mediators. 

Subsequently, the use of saliva for periodontal 

diagnosis and monitor response to treatment has 

been the subject of considerable research activity, 

and proposed markers for disease including 

enzymes, proteins, immunoglobulins, cytokines, 

host cells, etc.(2) 

 

 

 

 
(1) Asst. Prof.  Department of Basic Sciences, College of 

Dentistry, Hawler Medical University (Clinical Immunology) 

(2) Asst. Lect.  Department of Periodontology, College of 
Dentistry, Hawler Medical University (Periodontology) 

(3) Asst. Lect.  Department of Periodontology, College of 
Dentistry, Hawler Medical University (Periodontology) 

 

 
 

Periodontitis is an array of inflammatory diseases 

affecting the supporting tissues of teeth and 

resulting in periodontal pocket formation and 

alveolar bone resorption, which might eventually 

lead to tooth loss.  It is a chronic inflammatory 

disease associated with gram negative anaerobic 

bacteria present in the dental biofilm, leading to an 

excessive inflammatory response, which is 

influenced by several risk factors, such as stress 

and host-specific factors or habits, such as 

smoking.(3)  A complex interaction between these 

bacteria and host defensive capacity results in 

periodontal tissue breakdown.(4) The presence of 

periodontopathogens, such as Porphyromonas  
gingivalis,  Tannerella   forsythia, and   

Treponema denticola  is considered the 

predominant etiologic agents in periodontitis,(5) 

triggers the expression of proinflammatory 

cytokines, such as Interleukin-1(IL-1), Interleukin-

6(IL-6), Interleukin-8 (IL-8), tumor necrosis 

factor-α (TNF-α) and matrix metalloproteinases 

(MMPs), which have been related with the 

immunopathology of periodontitis. These 

mediators may affect the activities of leukocytes, 

osteoblasts and osteoclasts and stimulate the tissue 

remodelling process systematically and locally.(6)  

Interleukin-8 (IL-8), is formerly known as 
neutrophil-activating peptide-1 (NAP-1), a 

member of the CXC chemokine family, plays a 

significant role in the recruitment and activation of 



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neutrophil during inflammation.(7) IL-8 is 

predominantly produced by gingival endothelial 

cells, fibroblasts, keratinocytes and macrophages 

in response to periodontal bacterial and bacterial 

components. IL-8 is a potent pro-inflammatory 

cytokine that regulates alveolar bone resorption 

during tooth crusade by acting early in the 

inflammatory response,(7,8) thus directly 

contributing to the progression of the periodontal 

lesion.(8,9)  The expression of IL-8 mRNA and 

protein have been detected to be increased in 

chronically inflamed periodontal tissue, as well as 

gingival crevicular fluid of patients with 

periodontitis.(10,11) It is recognized that 

overproduction and excessive IL-8 mediated 

chemotactic and activation having effects on 

neutrophils in the inflamed gingiva may contribute 

to the periodontal tissue impairment.(12) 

Smoking is the major risk factor, which is closely 

related with extent and severity of periodontal 

diseases.(13) Cross-sectional studies have 

consistently shown that smokers are two to six 

times more likely to have severe periodontitis than 

non-smokers.(14) In addition, clinical studies have 

recognized that severe periodontal disease with 

increased bone loss, greater periodontal attachment 

loss, more gingival recession and periodontal 

pocket formation are more frequent in smoking 

patients with periodontitis compared to non-

smokers.(15,16) It is well established that smoking 

alters the host response, including changes 

vascular function, neutrophil/monocyte activities, 

adhesion molecule expression, cytokine and 

inflammatory mediator release, as well as antibody 

production.(17,18)  These changes likely contribute 

to the negative effect of smoking on the reparative 

and regenerative potential of the periodontium. 

Various studies have stated the possible role of IL-

8 in GCF as a biomarker for periodontal disease 

but less literature is available on its role in saliva. 

Based on these findings, it seems reasonable to 

speculate that IL-8 may influence the initiation and 

progression of periodontitis. Thus, the aim of 

present study was to assess the influence of 

smoking on periodontal health by estimating the 

IL-8 level in saliva of smokers and nonsmokers 

with chronic periodontitis. The IL-8 levels in 

saliva among individuals with healthy 

periodontium, smokers and non-smokers with 

periodontitis were also compared and correlated 

with clinical findings. 

 

  

MATERIALS AND METHODS 

Study population: 
The protocol for the present case-controlled study 

was approved by the Committee of ethics at 

College of dentistry/ Hawler Medical University. 

Written informed consent was obtained from all 

participants before conducting the study. 

Ninety male participants, aged between 25-50 

years old were selected by random sampling from 

patients attending outpatient clinics of the 

Department of Periodontitics at College of 

Dentistry, Hawler Medical University from 

February to August 2017. Subjects were 

categorized into three groups: Group-I comprised 

of 30 smokers with chronic periodontitis; Group-II 

comprised of 30 non-smokers with chronic 

periodontitis; and Group-III comprised of 30 non-

periodontitis and non-smoking controls. 

Periodontitis diagnosis was based on the 

classification of American Academy of 

Periodontology.(19) Patients with at least 30% of 

sites with loss of attachment were classified as 

having generalized chronic periodontitis and 

radiographic evidence of bone loss. Subjects must 

not have less than 20 standing teeth in their mouth. 

The periodontal patients group included 

individuals with probing pocket depth (PPD) ≥ 5 

mm and clinical attachment level (CAL) ≥ 3 mm 

(> 30% affected sites). Furthermore, current 

smokers who smoked ≥ 10 cigarettes per day for 

not less than 2 years and who fulfilled the criteria 

of chronic periodontitis, were enrolled in the study.  

The control group consisted of individuals without 

a history of periodontal disease and attachment 

loss, as well as probing pocket depth (PPD) ≤ 3 

mm.  

All the participants were systemically healthy; had 

no medical history or clinical evidence of any 

acute or chronic diseases; had no intraoral 

inflammatory and non- inflammatory lesions; had 

no history of antibiotic and anti-inflammatory drug 

treatment within the previous 6 months; had no 

history of scaling and root planning for at least 6 

months prior to sampling and recording.  

Saliva sampling and analysis: 
Unstimulated whole expectorated saliva (3 mL) 

was collected from each subject between 8:00 and 

11:00 A.M. (at least 2 hours after a meal) before 

doing periodontal examination according to a 

modification in the method described by 

Navazesh.(20) Subjects were requested to rinse their 
mouth with distilled water thoroughly to remove 

exfoliated cells and food debris, which they 



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expectorated at least 3 mL of un-stimulated whole 

saliva into a 5mL sterile tubes while seated in an 

upright position. Collected samples were placed 

immediately on ice pack, then transported to the 

laboratory and centrifuged at 3500 rpm for 10 

minutes. The supernatant structure was kept frozen 

at -40 ºC as aliquots till analysis. Salivary IL-8 

levels were measured with an ELISA kit using 

Human Interleukine-8(IL-8) provided by Expert 

chem SERV (Catalog # DRE10290) according to 

manufacturerʼs instructions. The standard range 

was 50ng/L- 1000 ng/L.                     

Clinical Parameters: 
Clinical measurements and radiographic 

examination of all participants were performed by 

a single experienced examiner after the collection 

of saliva sample. The Gingival index (GI),(21) 

plaque index (PI),(22) Probing pocket depth (PPD), 

Clinical attachment level (CAL) using UNC 15 

probe were measured at six sites  for all the present 

teeth except third molar.  

Statistical analysis: 
The descriptive data were expressed as mean and 

standard deviation (Mean ± SD). Comparison of 

clinical parameters of the three groups was 

analyzed using T-test and analysis of variance by 

one-way ANOVA test. Comparison of salivary IL-

8 level among three groups was analyzed by one-

way ANOVA test. Pair-wise comparison was 

performed by Tukey’s multiple comparison tests to 

determine the difference of salivary IL-8 level 

between the groups. Possible correlations between 

salivary IL-8 levels and clinical periodontal 

parameters were assessed by the Spearman’s 

Correlation Coefficients.  Statistical analyses were 

performed with SPSS version 22 (SPSS, Chicago, 

IL, USA), and P-value<0.05 were considered 

statistically significant. 
 

RESULTS  
The mean age of the participants was 39.10 ± 4.71 

years in Group I; 38.83 ± 3.29 years in Group II; 

and 38.40 ± 4.64 years in Group III with no 

significant differences among the three study 

groups (p > 0.05). 

All clinical periodontal parameters were 

significantly higher in the patients groups as 

compared to the healthy control. On the other 

hand, the mean PPD, CAL, and PI were 

significantly higher in the smokers group 
compared to non-smokers (P < 0.001), while the 

mean GI score among the smokers ( 1.30 ± 0.28) 

was significantly less than that of non-smokers    

(2.51 ± 0.39) (P < 0.001)  (Table 1). 

The mean values of salivary IL-8 levels in smoker 

and non-smoker periodontitis groups were higher 

than in the control group (Figure 1). Salivary IL-8 

level was significantly higher in smokers, followed 

in descending order by non-smokers and the 

controls with the mean values of (461.76 ± 329.66, 

257.83 ± 247.19, and 96.55 ± 62.35 ng/L) 

respectively. With respect to salivary IL-8 levels, a 

pair- wise comparison between the groups also 

showed a highly statistically significant results (p< 

0.01) (Table 2). By Spearman correlation 

coefficient analysis, in smokers and non-smokers 

with chronic periodontitis and control groups, 

salivary IL-8 levels did not show any significant 

correlation with clinical parameters of periodontal 

disease (PPD, CAL, PI, and GI) (all p > 0.05, data 

not shown).  
 

 
Figure 1: Mean levels of IL-8 in saliva of smoker and 

non-smoker periodontitis groups and control group 

 

DISCUSSION  
Smoking is one of the most important risk factors 

for periodontal disease. It has been shown that 

various components of tobacco smoke, nicotine act 

on the periodontal tissues causing destruction of 

the supporting tissues.(23) IL-8 is a multifunctional 

cytokine that plays a role in immune and 

inflammatory activities like recruitment and 

activation of neutrophils.(9) Thus, this study 

attempted to estimate and compare the level of IL-

8 in saliva of smokers and non-smokers with 

chronic periodontitis and correlate these levels 

with the severity of periodontal diseases.  

In the present study, smokers with chronic 

periodontitis had significantly increased PPD,  

 

 



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Table 1:  Comparison of the three groups with respect to clinical periodontal parameters. 

Clinical 

parameters§ 
Group I Group II Group III P-value 

PPD 5.82± 0.75 5.25 ± 0.27 1.97± 0.63 0.000* 

CAL 4.93± 1.07 3.90± 0.73 0.00± 0.00 0.000* 

PI 1.86± 0.42 1.27± 0.33 0.37± 0.15 0.000* 

GI 1.30 ± 0.28 2.51± 0.39 0.79± 0.27 0.000** 
§ values expressed as mean ± SD 

PPD=probing pocket depth, CAL= Clinical attachment level, PI=Plaque index, GI= gingival index 

Group I= Smoker, Group II= Nonsmoker, Group III= Control 

* Statistical difference at P< 0.05 by ANOVA test 

** Statistical difference at P< 0.05 by Kruskal-Wallis test   

Table 2:  Comparison of the three groups with respect to salivary IL-8 levels  

Study groups 
Salivary IL-8 

Comparison 
Mean differences 

P-value* 
Mean ± SD Mean ± SD 

Group I: Smoker 461.76 ± 329.66 I vs II 209.6 ± 364.91 0.004 

Group II: 

Nonsmoker 
257.83 ± 247.19 I vs III -209.6 ± 155.32 0.000 

Group III: Control 96.55 ± 62.35 II vs III -364.91 ± 155.32 0.030 

*Significance at P< 0.05 by HSD (honest significant difference) 

 

CAL, and PI, compared to non-smokers (P < 

0.001). However, the gingival index (GI) was 

significantly higher in non-smokers with chronic 

periodontitis than in smokers (P < 0.001). Previous 

studies (24,25) showed similar results. Jenifer et 
al.,(26) found a positive relationship between 

periodontal disease and smoking and have also 

reported a positive correlation with greater probing 

depth, attachment loss and plaque index in 

smokers. This supports the concept that smokers 

are generally presented with reduced gingival 

inflammation and bleeding on probing, compared 

to non-smokers, because smoking has a strong, 

chronic, dose-dependent suppressive effect on 

gingival inflammation and bleeding on probing.(27)  

Results significantly showed increased IL-8 levels 

in the saliva of smokers with periodontitis, 

compared to non-smokers with periodontitis and 

healthy controls (P< 0.001). Comparing between 

smoker with periodontitis and control group, 

salivary IL-8 level increased significantly and this 

relationship was highly significant (P < 0.001) the 

same results were obtained when non-smokers 

with chronic periodontitis and control group were 

compared. Again, there was significant increase in 

salivary IL-8 level (P < 0.001). Comparing smoker 
to non-smoker periodontitis groups, it was found 

that salivary IL-8 level increased significantly (P < 

0.001). Our results demonstrated that smoking 
significantly influences salivary IL-8 levels in 

periodontitis patients. 

Studies evaluating the effects of smoking on the 

expression of IL-8 level in periodontitis patients, 

have suggested that smoking increases the IL-8 

expression in GCF.(25,28)  It has also been reported 

that following periodontal therapy IL-8 levels 

decreased significantly in non-smokers, while in 

smokers it increased steadily and became 

significantly higher than in non-smokers.(28) It is 

primarily attributed to the fact that tobacco smoke 

activates more cells of the periodontium to express 

IL-8, thereby resulting in a local accumulation of 

polymorphonuclear cells (PMNʼs).(29) The results 

of our study explain the hypothesis that an 

exaggerated response by neutrophils occurs in 

response to increased IL-8 expression in smokers, 

suggesting an effect of smoking on the 

inflammatory responses against oral pathogens. 

Interestingly, increased GCF production of 

inflammatory molecules, such as IL-1β, IL-6, and 

IL-8, and suppression of anti-inflammatory 

molecules, such as IL-4, were discussed to imply 

increased periodontal destruction among 

smokers.(30) Moreover, Johnson et al.,(31) reported 

that nicotine can directly modify the production of 

cytokines and inflammatory mediators, causing 

increased IL-1, and IL-8 production by gingival 

keratinocytes. Nicotine also has a deleterious 

effect on the gingival and periodontal fibroblasts 

leading to further periodontal progression and 
periodontal tissue destruction.(32) A study on vitro 

by Lizheng  et al.,(32)  demonstrated  that nicotine 



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up-regulates the production of IL-1β and IL-8 via 

the α7nAChR/NF-κB pathway in human 

periodontal ligament cells (PDL), which could be 

inhibited by pretreatment with PDTC or α-BTX, 

suggested that α7nAChR/NF-κB pathway might 

play a key role in the up-regulation of these 

cytokines in smoking-associated periodontitis.(32) 

Altogether, these studies underline the important 

role of smoking by assessing potential markers for 

periodontitis. 

In contrast to our results, some studies have shown 

significantly lowered IL-8 level among smokers 

with chronic periodontitis in blood,(33) in GCF,(34) 

and salivary,(35) whereas other studies have 

reported no changes on the GCF levels of IL-

1β,IL-4,IL-6 and IL-8 among smokers and non-

smokers.(36) These studies have suggested that 

reduction in chemokines in smokers could 

contribute to the phenomena of impaired 

neutrophil chemotaxis and migration in the 

periodontium in spite of the presence of 

leucocytosis.(37) However, the increased level of 

salivary IL-8 in our study confirmed several 

findings in medical literature on positive 

association between smoking and increased 

expression of pro-inflammatory and chemokine 

molecules particularly IL-8. However, in the 

present study no correlation was found between 

clinical periodontal parameters PPD, CAL, PI, GI 

and salivary IL-8 levels. 
 

CONCLUSION 
In the present clinical cross-sectional study, 

smoking subjects showed increased level of 

salivary IL-8 and a worse periodontal condition 

than non-smoking subjects. Our results suggest 

that smoking alters an immune response which 

may contribute to an increased susceptibility to 

periodontal disease among smokers 

 

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 :ةالخالص
( يكون مشاركا  interleukin-8سيه المساهمه في التسبب و تطور مرض األنسجه ما حول الفم .)ان التدخين يعد احد العوامل الرئي  :هدف البحثو  ةخلفي 

( اللعابي interleukin-8في عملية تقدم و تطور حاله المرض من الناحيه المناعيه لمرض األنسجه ما حول الفم.تحديد تأثير التدخين على مستوى ال )

مرض األنسجه ما حول الفم و مقارنتها مغ أشخاص ال يشكون من مرض األنسجه ما حول الفم و   على مرضى)مدخنين و غير مدخنين( يعانون من 

   .(controlاعتبارهم عينه سيطرة)

سريريا على   30غير مدخن و  30مدخن و  30مشارك تم تصنيفهم على ثالث مجاميع :  90عينات من اللعاب الغير محفز تم جمعه من  :المواد والطرق

.المعايير السريريه مثل عمق الجيب اللثوي, مستوى فقدان االلتماس, فهرس البالك و فهرس اللثه تم قياسهم.  صحه تامه في ما يخص األنسجه ما حول الفم

 (. ELISAفي اللعاب تم قياسه بأستعمال عدة فحص  انزيم األرتباط المناعي  )  IL-8مستوى ال 

( اللعابي كان كبير جدا في مجموعه المدخنين الذين يعانون من من مرض  interleukin-8لتجربه لقد وجد ان معدل القيمه لل )من خالل هذه ا :النتائج

±  257.83( بالمقارنه مع غير المدخنين الذين يعانون من من مرض األنسجه ما حول الفم  ) ng/L 329.66±  461.76األنسجه ما حول الفم )

247.19 ng/Lوفي  مج ) ( موعه الcontrol(  )96.55  ±62.35 ng/L) (p < 0.001( اما مستويات  ال .)interleukin-8  اللعابي في الألشخاص )

 . p< 0.001) الذين يعانون المرض فقد كانت كبيره جدا في مجموعه المدخنين عنده مقارنتها مع غير المدخنين  )

( اللعابي ترافها تزايد في سوء حاله األنسجه ما حول الفم بالمقارنه مع غير interleukin-8ل )األشخاص المدخنين اظهرو مستويات مرتفعه ل  :األستنتاج

م بين المدخنين المدخنين. نتائجنا تقترح ان التدخين قد يغير في استجابه الجهاز المناعي و الذي قد يساهم في زيادة سوء حاله مرض األنسجه ما حول الف

 ما حول الفم .  الذين يعانون من مرض األنسجه