Effect of orthodontic forces on levels of enzymes in gingival crevicular fluid (GCF): A systematic review

Kapoor, Priyanka; Monga, Nitika; Kharbanda, Om Prakash; Kapila, Sunil; Miglani, Ragini; Moganty, Rajeswari

doi:10.1590/2177-6709.24.2.40.e1-22.onl

Abstract

Objective:

Orthodontic force application releases multiple enzymes in gingival crevicular fluid (GCF) for activation, resorption, reversal, deposition of osseous elements and extracellular matrix degradation. The current systematic review critically evaluated all existing evidence on enzymes in orthodontic tooth movement.

Methods:

Literature was searched with predetermined search strategy on electronic databases (PubMed, Scopus, Embase), along with hand search.

Results:

Initial search identified 652 studies, shortlisted to 52 studies based on PRISMA. Quality assessment further led to final inclusion of 48 studies (13 moderately and 35 highly sensitive studies). Primary outcomes are significant upregulation in GCF levels of enzymes-aspartate aminotransferase (AST), alkaline phosphatase (ALP), matrix metalloproteinases (MMPs), lactate dehydrogenase (LDH), β-glucuronidase (βG), tartrate resistant acid phosphatase (TRAP), acid phosphatase (ACP) and down regulation in cathepsin B (Cb). Site specificity is shown by ALP, TRAP, AST, LDH, MMP9 with levels at compression site increasing earlier and in higher quantities compared with tension site. ALP levels are higher at tension site only in retention. A positive correlation of LDH, ALP and AST is also observed with increasing orthodontic force magnitude.

Conclusions:

A strong evidence of variation in enzymes (ALP, AST, ACP TRAP, LDH, MMPs, Cb) in GCF is found in association with different magnitude, stages and sites of orthodontic force application.

Keywords:
Tooth movement; Gingival crevicular fluid (GCF); Enzymes; Systematic review

Resumo

Objetivo:

a aplicação da força ortodôntica libera múltiplas enzimas no fluído crevicular gengival (FCG), desencadeando a ativação, reabsorção, reversão, deposição de elementos ósseos e degradação da matriz extracelular. A presente revisão sistemática avaliou criticamente toda a evidência disponível sobre os níveis de enzimas durante a movimentação ortodôntica.

Métodos:

utilizando-se estratégias predeterminadas, foram realizadas buscas em bases de dados eletrônicas (PubMed, Scopus, Embase), sendo também feitas buscas manuais.

Resultados:

a busca inicial identificou 652 estudos e, com base nas diretrizes do PRISMA, foram selecionados 52 estudos. A avaliação qualitativa resultou na inclusão final de 48 estudos (13 estudos com moderada sensibilidade e 35 com alto nível de sensibilidade). Os desfechos primários foram o aumento significativo dos níveis no FCG das enzimas aspartato aminotransferase (AST), fosfatase alcalina (FA), metaloproteinases de matriz (MMPs), lactato desidrogenase (LDH), β-glucuronidase (βG), fosfatase ácido-resistente ao tartarato (TRAP), fosfatase ácida (FAC) e baixa regulação de catepsina B (Cb). Especificidade quanto ao local foi mostrada para FA, TRAP, AST, LDH e MMP9 com os níveis no lado de compressão aumentando mais rápido e em maiores quantidades, quando comparado ao lado de tensão. Os níveis de FA foram maiores no lado de tensão somente no período de contenção. Uma correlação positiva de LDH, FA e AST também foi observada à medida que a magnitude de força ortodôntica aumentou.

Conclusões:

há fortes evidências indicando que as variações nas enzimas (FA, AST, FAC, TRAP, LDH, MMPs, Cb) presentes no FCG estão associadas a diferentes magnitudes, estágios e locais de aplicação da força ortodôntica.

Palavras-chave:
Movimento dentário; Fluído crevicular gengival (FCG); Enzimas; Revisão sistemática

INTRODUCTION

Orthodontic forces cause an initial inflammatory response followed by alterations in the vascular and neural envelope and perpetual bone and tissue remodelling accompanied by paracrine release of bioactive mediators.¹1 Meeran NA. Cellular response within the periodontal ligament on application of orthodontic forces. J Indian Soc Periodontol. 2013;17(1):16-20.

2 Krishnan V, Davidovitch Z. Cellular, molecular, and tissue-level reactions to orthodontic force. Am J Orthod Dentofacial Orthop. 2006 Apr;129(4):469.e1-32.^-³3 Alhadlaq AM. Biomarkers of orthodontic tooth movement in gingival crevicular fluid: a systematic review. J Contemp Dent Pract. 2015;16(7):578-87. During orthodontic tooth movement (OTM), host-derived enzymes are released at various stages of activation, resorption, reversal and deposition of osseous elements and degradation of the extracellular matrix.⁴4 Apuzzo F, Cappabianca S, Ciavarella D, Monsurrò A, Silvestrini-Biavati A, Perillo L. Biomarkers of periodontal tissue remodeling during orthodontic tooth movement in mice and men: overview and clinical relevance. Sci World J. 2013 Apr 23;2013:105873. Some of these enzymes have been identified in the periodontal (pdl) tissue of orthodontically moved teeth.⁵ Gingival crevicular fluid (GCF) is however a better choice for assessing biomolecules or mediators as sample collection is simple, sensitive, convenient, repetitive and non-invasive.⁶6 Kapoor P, Kharbanda OP, Monga N, Miglani R, Kapila S. Effect of orthodontic forces on cytokine and receptor levels in gingival crevicular fluid: a systematic review. Prog Orthod. 2014 Dec 9;15:65. Thus, the quantitative estimations of mediators in GCF reflect biochemical mechanisms associated with OTM. A systematic review (SR) by Kapoor et al⁶6 Kapoor P, Kharbanda OP, Monga N, Miglani R, Kapila S. Effect of orthodontic forces on cytokine and receptor levels in gingival crevicular fluid: a systematic review. Prog Orthod. 2014 Dec 9;15:65. in 2014 studied variation in GCF level of cytokines with type and magnitude of orthodontic forces and growth status of patients. It established a positive correlation of GCF activity index IL1RA (interleukin receptor antagonist)/ IL-1β) with intensity of pain and velocity of OTM and a negative correlation with growth status of patients. Besides cytokines, numerous other mediators also alter GCF during OTM, comprehensively reviewed in SR by Alhadlaq³3 Alhadlaq AM. Biomarkers of orthodontic tooth movement in gingival crevicular fluid: a systematic review. J Contemp Dent Pract. 2015;16(7):578-87. in 2015. This SR highlighted working mechanisms of multiple mediators but heterogeneity of studies precluded attainment of concrete conclusions. Hence, the present SR aims to assess only a single family of mediators, enzymes, to establish their clinical correlations on sequential release in different phases of OTM and varying magnitude of orthodontic forces.

Soluble enzymes like lactate dehydrogenase (LDH) and aspartate aminotransferase (AST) present in cytoplasm are known to release in GCF only after cellular necrosis or hyalinization with heavy orthodontic forces.⁴4 Apuzzo F, Cappabianca S, Ciavarella D, Monsurrò A, Silvestrini-Biavati A, Perillo L. Biomarkers of periodontal tissue remodeling during orthodontic tooth movement in mice and men: overview and clinical relevance. Sci World J. 2013 Apr 23;2013:105873. Tartrate-resistant acid phosphatase (TRAP) and alkaline phosphatase (ALP) exhibit osteoclastic and osteoblastic activity, respectively,¹1 Meeran NA. Cellular response within the periodontal ligament on application of orthodontic forces. J Indian Soc Periodontol. 2013;17(1):16-20. and are identified in areas of tension (TS) or compression (CS) of teeth undergoing OTM. Heavy orthopedic forces of rapid maxillary expansion show an increase of ß-glucuronidase (ßG) lysosomal enzyme upon release from polymorphonuclear (PMN) leukocytes.⁷7 Tzannetou S, Efstratiadis S, Nicolay O, Grbic J andLamster I. Comparison of levels of inflammatory mediators IL-1beta and betaG in gingival crevicular fluid from molars, premolars, and incisors during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 2008;133(5):699-707. Rise in PMN granules in surrounding tissues after fixed orthodontic appliance activation also show increase in myeloperoxidase (MPO) 2 hours (hr) after activation, traced both in GCF and saliva.⁸8 Marcaccini AM, Amato PA, Leão FV, Gerlach RF, Ferreira JT. Myeloperoxidase activity is increased in gingival crevicular fluid and whole saliva after fixed orthodontic appliance activation. Am J Orthod Dentofacial Orthop. 2010 Nov;138(5):613-6.

The evidence on enzymes in OTM is plenty but scattered and lacks critical appraisal. Hence, the current SR is conducted to establish associations of enzymes in GCF to the site of application, magnitude and type of force, patient’s growth status and the type of archwire ligation.

MATERIAL AND METHODS

Protocol and registration

The protocol for SR was registered in PROSPERO (www.crd.york.ac.uk/prospero, CRD42015017496) with a predetermined search strategy (Fig 1). It comprised of MeSH terms, Boolean terminology and free text terms with the keywords "enzyme" "protease", "orthodontic tooth movement" and "gingival crevicular fluid", together with several key enzymes. This search strategy was applied to key databases PubMed, Scopus and Embase in February 2018 with no language restrictions. Additional publications were identified through reference tracking and hand search of journals (Sains Malaysiana, Orthodontic Waves, Journal of Applied Sciences, APMC). The search was performed by two reviewers, followed by a cross-check by a third reviewer, in conformity with PRISMA, as shown in Figure 2.

Figure 1
Search strategy applied on databases for inclusion of studies in the review.

Figure 2
PRISMA flow diagram for inclusion of studies in the systematic review

Evaluation of risk of bias / quality of individual studies

The risk of bias, subjective to the included studies was measured by a customized Quality Assessment Instrument (QAI)⁶6 Kapoor P, Kharbanda OP, Monga N, Miglani R, Kapila S. Effect of orthodontic forces on cytokine and receptor levels in gingival crevicular fluid: a systematic review. Prog Orthod. 2014 Dec 9;15:65. based on QUADAS. This was objectively scored as minimally (scores of 1-12), moderately (13-20) and highly (21-29) sensitive, summarized in Table 1. No minimally sensitive studies were included in the review.

Thumbnail

Table 1
Inclusion and Exclusion criteria applied for inclusion of studies in the systematic review.

RESULTS

Were identified 102 articles in Pubmed, 460 in Scopus, 84 in Embase and 6 from hand search, in the initial search. Strict inclusion and exclusion criteria (Table 2) were applied after removing duplicates, resulting in 41 relevant articles. Five studies were further excluded: three studies whose full texts were not retrieved despite contacting the authors repeatedly through mail and academic social networking sites; one was a review on MMPs, and one had sample size smaller than inclusion criteria. Additional exclusion of three studies was done: two with QAI score smaller than 13, and one with a cross-sectional study design (Fig 2).

Thumbnail

Table 2
Quality Assessment Instrument (QAI) customized from QUADAS (Quality Assessment of Diagnostic Accuracy Studies) tool for assessment of risk of bias for inclusion of studies in the review.

PRISMA finally resulted in 48 publications in total, with consensus among all reviewers. The QAI of these studies indicated 13 moderately sensitive and 35 highly sensitive studies.

Data extraction of shortlisted studies⁷7 Tzannetou S, Efstratiadis S, Nicolay O, Grbic J andLamster I. Comparison of levels of inflammatory mediators IL-1beta and betaG in gingival crevicular fluid from molars, premolars, and incisors during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 2008;133(5):699-707.

8 Marcaccini AM, Amato PA, Leão FV, Gerlach RF, Ferreira JT. Myeloperoxidase activity is increased in gingival crevicular fluid and whole saliva after fixed orthodontic appliance activation. Am J Orthod Dentofacial Orthop. 2010 Nov;138(5):613-6.

9 Alswafeeri H, ElKenany W, Mowafy M, Helmy M. Crevicular alkaline phosphatase activity during the application of two patterns of orthodontic forces. J Orthod. 2015;42(1):5-13.

10 Alfaqeeh SA, Anil S. Gingival crevicular fluid flow rate and alkaline phosphatase level as potential marker of active tooth movement. Oral Health Dent Manag. 2014 June;13(2):458-63.

11 Abdul Wahab RM, Abu Kasim N, Senafi S, Jemain AA, Zainol Abidin IZ, Shahidan MA, et al. Enzyme activity profiles and ELISA analysis of biomarkers from human saliva and gingival crevicular fluid during orthodontic tooth movement using self-ligating brackets. Oral Health Dent Manag. 2014 June;13(2):194-9.

12 Navarro-Palacios A, García-López E, Meza-Rios A, Armendariz-Borunda J, Sandoval-Rodríguez A. Myeloperoxidase enzymatic activity is increased in patients with different levels of dental crowding after initial orthodontic activation. Am J Orthod Dentofacial Orthop. 2014 July;146(1):92-7.

13 Surlin P, Silosi I, Rauten AM, Cojocaru M, Foia L. Involvement of TSP1 and MMP9/NGAL in angiogenesis during orthodontic periodontal remodeling. Sci World J. 2014;2014:421029.

14 Kulal R, Thomas B, Ravi MS, Shetty S. Enzymatic evaluation of gingival crevicular fluid in cleft palate patients during orthodontic treatment: a clinico-biochemical study. J Indian Soc Periodontol. 2013;17(3):319-23.

15 Rody WJ Jr, Wijegunasinghe M, Wiltshire WA, Dufault B. Differences in the gingival crevicular fluid composition between adults and adolescents undergoing orthodontic treatment. Angle Orthod. 2014;84(1):120-6.

16 Bolamperti L, Montanari P, Levrini L, Macchi A, Tagliabue A, Caprioglio A. Tissue response during self-ligating treatment. Prog Orthod. 2012;13(2):109-16.

17 Canavarro C, Teles RP, Capelli Júnior J. Matrix metalloproteinases -1, -2, -3, -7, -8, -12, and -13 in gingival crevicular fluid during orthodontic tooth movement: a longitudinal randomized split-mouth study. Eur J Orthod .2013;35(5):652-8.

18 Grant M, Wilson J, Rock P, Chapple I. Induction of cytokines, MMP9, TIMPs, RANKL and OPG during orthodontic tooth movement. Eur J Orthod. 2013;35(5):644-51.

19 Alfaqeeh SA, Anil S. Lactate dehydrogenase activity in gingival crevicular fluid as a marker in orthodontic tooth movement. Open Dent J. 2011;5:105-9.

20 Capelli J Jr, Kantarci A, Haffajee A, Teles RP, Fidel R Jr, Figueredo CM. Matrix metalloproteinases and chemokines in the gingival crevicular fluid during orthodontic tooth movement. Eur J Orthod. 2011;33(6):705-11.

21 Rhee SH, Kang J, Nahm DS. Cystatins and cathepsin B during orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2009;135(1):99-105.

22 Cantarella G, Cantarella R, Caltabiano M, Risuglia N, Bernardini R, Leonardi R. Levels of matrix metalloproteinases 1 and 2 in human gingival crevicular fluid during initial tooth movement. Am J Orthod Dentofacial Orthop. 2006;130(5):568.e11-6.

23 Hoshino-Itoh J, Kurokawa A, Yamaguchi M, Kasai K. Levels of t-PA and PAI-2 in gingival crevicular fluid during orthodontic tooth movement in adults. Aust Orthod J. 2005;21(1):31-7.

24 Batra P, Kharbanda OP, Duggal R, Singh N, Parkash H. Alkaline phosphatase activity in gingival crevicular fluid during canine retraction. Orthod Craniofac Res. 2006;9(1):44-51.

25 Isik F, Sayinsu K, Arun T, Unlüçerçi Y. Bone marker levels in gingival crevicular fluid during orthodontic intrusive tooth movement: a preliminary study. J Contemp Dent Pract. 2015;6(2):27-35.

26 Perinetti G, Serra E, Paolantonio M, Bruè C, Meo SD, Filippi MR, et al. Lactate dehydrogenase activity in human gingival crevicular fluid during orthodontic treatment: a controlled, short-term longitudinal study. J Periodontol. 2005;76(3):411-7.

27 Ingman T, Apajalahti S, Mäntylä P, Savolainen P, Sorsa T. Matrix metalloproteinase-1 and -8 in gingival crevicular fluid during orthodontic tooth movement: a pilot study during 1 month of follow-up after fixed appliance activation. Eur J Orthod. 2005;27(2):202-7.

28 Perinetti G, Paolantonio M, Serra E, D'Archivio D, D'Ercole S, Festa F, et al. Longitudinal monitoring of subgingival colonization by Actinobacillus actinomycetemcomitans, and crevicular alkaline phosphatase and aspartate aminotransferase activities around orthodontically treated teeth. J Clin Periodontol 2004;31(1):60-7.

29 Sugiyama Y, Yamaguchi M, Kanekawa M, Yoshii M, Nozoe T, Nogimura A, Kasai K. The level of cathepsin B in gingival crevicular fluid during human orthodontic tooth movement. Eur J Orthod. 2003;25(1):71-6.

30 Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Tripodi D, Femminella B, et al. Alkaline phosphatase activity in gingival crevicular fluid during human orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2002;122(5):548-56.

31 Tzannetou S, Efstratiadis S, Nicolay O, Grbic J, Lamster I. Interleukin-1 beta and beta-glucuronidase in gingival crevicular fluid from molars during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 1999;115(6):686-96.

32 Uematsu S, Mogi M, Deguchi T. Interleukin (IL)-1 beta, IL-6, tumor necrosis factor-alpha, epidermal growth factor, and beta 2-microglobulin levels are elevated in gingival crevicular fluid during human orthodontic tooth movement. J Dent Res. 1996;75(1):562-7.

33 Karaduman B, Uraz A, Altan GN, Tuncer BB, Alkan O, Gönen S, et al. Changes of tumor necrosis factor-?, interleukin-10, and tartrate-resistant acid phosphatase 5b in the crevicular fluid in relation to orthodontic movement. Eur J Inflamm. 2015;13(1):3-13.

34 Wahab RMA, Yamamoto R, Sintian A, Kasim NA, Abidin IZZ, Senafi S, et al. The effects of orthodontic forces during canine retraction using self- ligating brackets on gingival crevicular fluid enzyme activity, canine movement and root resorption. Sains Malaysiana. 2015;44(2):249-56.

35 Ariffin SHZ, Kasim NA, Wahab RMA, Jemain AA. Lactate dehydrogenase activity during tooth movement under 1.0 N and 1.5 N continuous force applications. Sains Malaysiana. 2013;42(1):99-105.

36 Wahab RMA, Dasor MM, Senafi S, Abdullah AAA, Jemain AA, Kasim NA, et al. Crevicular tartrate resistant acid phosphatase activity and rate of tooth movement under different continuous force applications. African J Pharmacy Pharmacol. 2011;5(20):2213-9.

37 Abdullah AAA, Wahab RMA, Ariffin SHBZ. Pattern of crevicular alkaline phosphatase during orthodontic tooth movement: leveling and alignment stage. Sains Malaysiana. 2011;40(10):1147-51.

38 Asma AAA, Rohaya MAW, Hisham ZAS. Crevicular alkaline phosphatase activity during orthodontic tooth movement: canine retraction stage. J Med Sci. 2008;8(3):228-33.

39 Rohaya MAW, Hisham ZAS, Khazlina K. The activity of aspartate aminotransferase during canine retraction (bodily tooth movement) in orthodontic treatment. J Med Sci. 2008;8:553-8.

40 Rohaya MAW, Hisham ZAS, Khazlina K. Preliminary study of aspartate aminotransferase activity in gingival crevicular fluids during orthodontic tooth movement. J Applied Sci. 2009;9(7):1393-96.

41 Hassan KS, Alagl SA, Ali I. Periodontal status following self-ligature versus archwire ligation techniques in orthodontically treated patients: Clinical, microbiological and biochemical evaluation. Orthod Waves. 2010;69:164-70.

42 Farahani M, Safavi MS, Dianat O, Tusi SK, Younessian F. Acid and alkaline phosphatase levels in gcf during orthodontic tooth movement. J Dent Shiraz Univ Med Sci. 2015;16(3 Suppl): 237-45.

43 Jeyraj Y, Katta AK, Vannala V, Lokanathan D, Reddy SN, Rajasigamani K. Estimation of alkaline phosphatase in the gingival crevicular fluid during orthodontic tooth movement in premolar extraction cases to predict therapeutic progression. J Nat SciBiolMed. 2015;6(2):343-6.

44 Perinetti G, D'Apuzzo F, Contardo L, Primozic J, Rupel K, Perillo L. Gingival crevicular fluid alkaline phosphate activity during the retention phase of maxillary expansion in prepubertal subjects: A split-mouth longitudinal study. Am J Orthod Dentofacial Orthop. 2015 July;148(1):90-6.

45 Arifyezdani A. Alkaline phosphatase activity in gingival crevicular fluid: a diagnostic marker to assess human orthodontic tooth movement. Biomed Pharmacol J. 2015;8(Spl. Edn): 293-301.

46 Arifyezdani A. Acid phosphatase activity in gingival crevicular fluid during human orthodontic tooth movement. Biomed Pharmacol J. 2015; 8(Spl. Edn):403-8.

47 Lakshmanan P, Sathya PB, Dilip S, Srinivas S. Evaluation of lactate dehydrogenase levels in gingival crevicular fluid during orthodontic tooth movement an in-vivo study. Res J Pharmaceutical Biol Chem Sci. 2015;6(5):877-88.

48 Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Dolci M, Femminella B, et al. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic treatment. A controlled short-term longitudinal study. J Periodontol. 2003;74(2):145-52.

49 Kalha AS, Kachiwala VA, Govardhan SN, McLaughlin RP, Khurshaid SZ. Redefining orthodontic space closure: sequential repetitive loading of the periodontal ligament-a clinical study. World J Orthod. 2010;11(3):221-9.

50 Saloom HF, Papageorgiou SN, Carpenter GH, Cobourne MT. Impact of obesity on orthodontic tooth movement in adolescents: a prospective clinical cohort study. J Dent Res. 2017;96(5):547-54.

51 Delli Mauri A, Petrini M, Vitale D, Tecco S, Festa F, Barbato E, et al. Alkaline phosphatase level in gingival crevicular fluid during treatment with Quad-Helix. J Biol Regul Homeost Agents. 2015 Oct-Dec;29(4):1017-23.

52 Fatima A, Talapaneni AK, Saleh A, Sana S, Hussain A. An evaluation and comparison of myeloperoxidase enzymatic activity during initial orthodontic alignment: an in vivo study. J Orthod. 2017 Sept;44(3):169-173.

53 Bhasin V, Singh M, Goutam M, Singh S, Nigam AS, Joshi A. Comparative evaluation of myeloperoxidase enzymatic activity in gingival crevicular fluid of subjects having orthodontic treatment by different aligning arch wires. J Contemp Dent Pract. 2017;18(10):977-80.^-⁵⁴54 Haq AU, Iqbal J, Hussain K, Munir A, Irfan S. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic tooth movement. APMC. 2017;11(2):149-53. (for participant characteristics and study design are as follows (Table 3):

Thumbnail

Table 3
Participant and study characteristics table.

» Sample size: Sample size was categorized in three groups, ≤15 (n=22), 15-20 (n=15), ≥21 (n=10) and one study each having sample of five subjects²⁷27 Ingman T, Apajalahti S, Mäntylä P, Savolainen P, Sorsa T. Matrix metalloproteinase-1 and -8 in gingival crevicular fluid during orthodontic tooth movement: a pilot study during 1 month of follow-up after fixed appliance activation. Eur J Orthod. 2005;27(2):202-7. and 99 subjects.²¹21 Rhee SH, Kang J, Nahm DS. Cystatins and cathepsin B during orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2009;135(1):99-105.
» Sex predilection: Forty- one studies mentioned sex distribution in the sample, two of which had female subjects only,²⁴24 Batra P, Kharbanda OP, Duggal R, Singh N, Parkash H. Alkaline phosphatase activity in gingival crevicular fluid during canine retraction. Orthod Craniofac Res. 2006;9(1):44-51.^,³⁶36 Wahab RMA, Dasor MM, Senafi S, Abdullah AAA, Jemain AA, Kasim NA, et al. Crevicular tartrate resistant acid phosphatase activity and rate of tooth movement under different continuous force applications. African J Pharmacy Pharmacol. 2011;5(20):2213-9. and five had equal numbers of male and female subjects.¹⁰10 Alfaqeeh SA, Anil S. Gingival crevicular fluid flow rate and alkaline phosphatase level as potential marker of active tooth movement. Oral Health Dent Manag. 2014 June;13(2):458-63.^,¹⁹19 Alfaqeeh SA, Anil S. Lactate dehydrogenase activity in gingival crevicular fluid as a marker in orthodontic tooth movement. Open Dent J. 2011;5:105-9.^,²³23 Hoshino-Itoh J, Kurokawa A, Yamaguchi M, Kasai K. Levels of t-PA and PAI-2 in gingival crevicular fluid during orthodontic tooth movement in adults. Aust Orthod J. 2005;21(1):31-7.^,²⁹29 Sugiyama Y, Yamaguchi M, Kanekawa M, Yoshii M, Nozoe T, Nogimura A, Kasai K. The level of cathepsin B in gingival crevicular fluid during human orthodontic tooth movement. Eur J Orthod. 2003;25(1):71-6.^,⁴³43 Jeyraj Y, Katta AK, Vannala V, Lokanathan D, Reddy SN, Rajasigamani K. Estimation of alkaline phosphatase in the gingival crevicular fluid during orthodontic tooth movement in premolar extraction cases to predict therapeutic progression. J Nat SciBiolMed. 2015;6(2):343-6.
» Age predilection: Studies used age as either range or mean with standard deviation in all studies; one study considered two separate age groups of adolescents and adults.¹⁵15 Rody WJ Jr, Wijegunasinghe M, Wiltshire WA, Dufault B. Differences in the gingival crevicular fluid composition between adults and adolescents undergoing orthodontic treatment. Angle Orthod. 2014;84(1):120-6.
» Number of studies reporting enzymes: Alkaline phosphatase was evaluated in maximum number of studies (n=17), closely followed by AST in 10, matrix metalloproteinases (MMPs) in eight, LDH in six, MPO in five and TRAP in four and acid phosphatase (ACP) in three studies. Two studies studied βG, cathepsin (Cp) and tissue inhibitor of MMPs (TIMPs) each. Single studies evaluated cystatin (Cys) and thrombospondin1 (TSP1). Additionally, granulocyte-macrophage colony-stimulating factor (GMCSF), epidermal growth factor (EGF), macrophage inflammatory protein-1β (MIP-1 β), methyl-accepting chemotaxis protein-1 (MCP-1), chemokine RANTES (Regulated on activation normal T cells expressed and secreted) were evaluated as secondary outcomes.
» Study duration: The duration of studies ranged from 8 hr to 24 weeks (wk) to the maximum of one year (y). One study each was done for 8hr, 1wk, 5month (m) and 1y duration, two studies for 6m, three for 2m, five each for 2wk and 3m, eight for 3wk, 15 for approximately 1m. One study did not specify duration - only completion of alignment.
» Observation intervals for GCF collection: Studies had GCF collection at repeated observation time points (OTP) ranging from 2 times²⁸28 Perinetti G, Paolantonio M, Serra E, D'Archivio D, D'Ercole S, Festa F, et al. Longitudinal monitoring of subgingival colonization by Actinobacillus actinomycetemcomitans, and crevicular alkaline phosphatase and aspartate aminotransferase activities around orthodontically treated teeth. J Clin Periodontol 2004;31(1):60-7. to 31 times (each day of the month).²⁷ Six OTPs were taken in 16 studies, closely followed by 4 OTPs in 15 studies, 9 OTPs in nine studies, 3 and 10 OTPs in two studies each, 2, 7, 8 and 31 OTPs in single study each.
» Site for GCF collection: Forty one studies specified mesial or distal or buccal site for GCF collection while seven studies mentioned the tooth but not the site for sample retrieval. The technique by Lamster et al.⁵⁵ utilizing six sites was used in four studies.¹⁰10 Alfaqeeh SA, Anil S. Gingival crevicular fluid flow rate and alkaline phosphatase level as potential marker of active tooth movement. Oral Health Dent Manag. 2014 June;13(2):458-63.^,¹⁹19 Alfaqeeh SA, Anil S. Lactate dehydrogenase activity in gingival crevicular fluid as a marker in orthodontic tooth movement. Open Dent J. 2011;5:105-9.^,³³33 Karaduman B, Uraz A, Altan GN, Tuncer BB, Alkan O, Gönen S, et al. Changes of tumor necrosis factor-?, interleukin-10, and tartrate-resistant acid phosphatase 5b in the crevicular fluid in relation to orthodontic movement. Eur J Inflamm. 2015;13(1):3-13.^,⁴⁴44 Perinetti G, D'Apuzzo F, Contardo L, Primozic J, Rupel K, Perillo L. Gingival crevicular fluid alkaline phosphate activity during the retention phase of maxillary expansion in prepubertal subjects: A split-mouth longitudinal study. Am J Orthod Dentofacial Orthop. 2015 July;148(1):90-6.^,⁴⁷47 Lakshmanan P, Sathya PB, Dilip S, Srinivas S. Evaluation of lactate dehydrogenase levels in gingival crevicular fluid during orthodontic tooth movement an in-vivo study. Res J Pharmaceutical Biol Chem Sci. 2015;6(5):877-88.
» Mechanics of force: Studies used continuous force both for tooth retraction (26 studies) and leveling of arches (13 studies). Retraction involved 19 studies using NiTi coil spring, two using steel ligature lacebacks, three using NiTi push coil spring, and one study each for V loop and NiTi open coil spring. Besides, nine studies used intermittent orthodontic/orthopaedic forces, employing elastomeric chain for retraction in five, Hyrax for expansion in three, and TMA spring for intrusion in one study.
» The level of force: Only 33 studies mentioned force levels for OTM. The level of forces ranged from 50g, 50-75g, 100-150g, 16N/turn, 1-1.5N, 200cN, 400g in one study each, 125g in three, 100g in six, 250g in eight and 150g in seven studies. Few studies had different treatment groups employing variable magnitudes of force.⁹9 Alswafeeri H, ElKenany W, Mowafy M, Helmy M. Crevicular alkaline phosphatase activity during the application of two patterns of orthodontic forces. J Orthod. 2015;42(1):5-13.^,¹¹11 Abdul Wahab RM, Abu Kasim N, Senafi S, Jemain AA, Zainol Abidin IZ, Shahidan MA, et al. Enzyme activity profiles and ELISA analysis of biomarkers from human saliva and gingival crevicular fluid during orthodontic tooth movement using self-ligating brackets. Oral Health Dent Manag. 2014 June;13(2):194-9.^,³⁴34 Wahab RMA, Yamamoto R, Sintian A, Kasim NA, Abidin IZZ, Senafi S, et al. The effects of orthodontic forces during canine retraction using self- ligating brackets on gingival crevicular fluid enzyme activity, canine movement and root resorption. Sains Malaysiana. 2015;44(2):249-56.^,³⁵35 Ariffin SHZ, Kasim NA, Wahab RMA, Jemain AA. Lactate dehydrogenase activity during tooth movement under 1.0 N and 1.5 N continuous force applications. Sains Malaysiana. 2013;42(1):99-105.^,³⁶36 Wahab RMA, Dasor MM, Senafi S, Abdullah AAA, Jemain AA, Kasim NA, et al. Crevicular tartrate resistant acid phosphatase activity and rate of tooth movement under different continuous force applications. African J Pharmacy Pharmacol. 2011;5(20):2213-9.

Oral hygiene regimen and gingival health assessment (Table 4)

Thumbnail

Table 4
Oral hygiene regimen.

GCF characteristics (Table 5)

Thumbnail

Table 5
GCF characteristics.

» GCF collection: GCF was collected by Periopaper (OraFlow, Plainview, New York, NY, USA) in 32 studies, micropipette in seven, filter paper in two, paper point in two and endodontic paper strip in five studies. Time of sample collection, room temperature and humidity conditions were specified in three studies each.

» GCF handling: Depth of Periopaper insertion was 1mm in 21 studies, 1-2mm in two, and 2mm in one study. Duration of GCF collection was 30 seconds (s) in 21 studies, 60s in 13 studies and 10s, 3 minutes (min) and 5 min in one study each. GCF measurements were repeatedly taken in 18 studies with specified number of intervals, interval of repeat measurements were 30s (n=8), 60s (n=7), 90s (n=3) and 5s (n=2). Storage of samples was done at -20^oC (n=5), -30^oC (N=4), -40^oC (n=3), -70^oC (n=11) and -80^oC (n=9). Retrieval of GCF from Periopaper was done by Periotron (OraFlow, PlainView, New York, NY, USA) in 11 studies, but not mentioned in 38 studies. Enzymes levels were estimated by ELISA (n=8), spectrophotometry (n=30), immunoassay (n=2), Luminexmultianalyte technology (n=1), Quantibody Array kit (n=1), western blotting (n=3), fluorometry (n=1) and para-nitrophenol phosphate kinetic (n=1), but omitted in one study. Protein concentration in GCF was measured in variable units in 38 out of 42 studies.

DISCUSSION

The findings of the current review are presented in Table 6. It depicts various enzymes released in GCF in a time-dependent manner and also establishes correlations (if any) with levels or type of force applied. In this review, we have tried to establish associations of enzyme levels to magnitude or type of force in each phase of OTM, given by Burstone⁵⁶56 Burstone CJ. The biomechanics of tooth movement. In: Kraus BS, Riedel RA, editors. Vistas in Orthodontics. Philadelphia: Lea & Febiger; 1962. p. 197-213. in his classic model or four phase time/displacement modification model.⁵⁷57 Pilon JJ, Kuijpers-Jagtman AM, Maltha JC. Magnitude of orthodontic forces and rate of bodily tooth movement: an experimental study in beagle dogs. Am J Orthod Dentofacial Orthop. 1996 Jul;110(1):16-23.^,⁵⁸58 van Leeuwen EJ, Maltha JC, Kuijpers-Jagtman AM. Tooth movement with light continuous and discontinuous forces in beagle dogs. Eur J Oral Sci. 1999 Dec;107(6):468-74.

Thumbnail

Table 6
Differential expression of enzymes in GCF.

An initial upregulation in enzymes for bone resorption and matrix degradation like TRAP, ACP or MMPs and an immediate decrease in bone formative ALP corresponded with Burstone’s initial phases of OTM. Different MMPs responsible for extracellular matrix (ECM) breakdown are increased at variable times in OTM,¹³13 Surlin P, Silosi I, Rauten AM, Cojocaru M, Foia L. Involvement of TSP1 and MMP9/NGAL in angiogenesis during orthodontic periodontal remodeling. Sci World J. 2014;2014:421029.^,¹⁵15 Rody WJ Jr, Wijegunasinghe M, Wiltshire WA, Dufault B. Differences in the gingival crevicular fluid composition between adults and adolescents undergoing orthodontic treatment. Angle Orthod. 2014;84(1):120-6.^,¹⁷17 Canavarro C, Teles RP, Capelli Júnior J. Matrix metalloproteinases -1, -2, -3, -7, -8, -12, and -13 in gingival crevicular fluid during orthodontic tooth movement: a longitudinal randomized split-mouth study. Eur J Orthod .2013;35(5):652-8.^,¹⁸18 Grant M, Wilson J, Rock P, Chapple I. Induction of cytokines, MMP9, TIMPs, RANKL and OPG during orthodontic tooth movement. Eur J Orthod. 2013;35(5):644-51.^,²⁰20 Capelli J Jr, Kantarci A, Haffajee A, Teles RP, Fidel R Jr, Figueredo CM. Matrix metalloproteinases and chemokines in the gingival crevicular fluid during orthodontic tooth movement. Eur J Orthod. 2011;33(6):705-11.^,²²22 Cantarella G, Cantarella R, Caltabiano M, Risuglia N, Bernardini R, Leonardi R. Levels of matrix metalloproteinases 1 and 2 in human gingival crevicular fluid during initial tooth movement. Am J Orthod Dentofacial Orthop. 2006;130(5):568.e11-6.^,²⁷27 Ingman T, Apajalahti S, Mäntylä P, Savolainen P, Sorsa T. Matrix metalloproteinase-1 and -8 in gingival crevicular fluid during orthodontic tooth movement: a pilot study during 1 month of follow-up after fixed appliance activation. Eur J Orthod. 2005;27(2):202-7.^,⁵⁰50 Saloom HF, Papageorgiou SN, Carpenter GH, Cobourne MT. Impact of obesity on orthodontic tooth movement in adolescents: a prospective clinical cohort study. J Dent Res. 2017;96(5):547-54. as early as 1hr or till completion of alignment.⁵⁰50 Saloom HF, Papageorgiou SN, Carpenter GH, Cobourne MT. Impact of obesity on orthodontic tooth movement in adolescents: a prospective clinical cohort study. J Dent Res. 2017;96(5):547-54. MMP-9 increased in 4hr, peaked at 8hr using stainless steel ligatures for canine retraction in one study, while MMP9/NGAL ratio peaked in 72hr in another study.¹³13 Surlin P, Silosi I, Rauten AM, Cojocaru M, Foia L. Involvement of TSP1 and MMP9/NGAL in angiogenesis during orthodontic periodontal remodeling. Sci World J. 2014;2014:421029.

MMPs also varied with different magnitudes of force as MMP-9 peaked in 4hr in a study using 100g force for canine retraction,¹⁸18 Grant M, Wilson J, Rock P, Chapple I. Induction of cytokines, MMP9, TIMPs, RANKL and OPG during orthodontic tooth movement. Eur J Orthod. 2013;35(5):644-51. compared to another study using 150g force in which MMP3, 9 and 13 peaked in 24hr.²⁰ The difference in peaks of various MMPs can be explained on the basis of difference in their roles in bone turnover and remodeling with orthodontic forces.⁵⁹59 Apajalahti S, Sorsa T, Railavo S, Ingman T. The in vivo levels of matrix metalloproteinase-1 and -8 in gingival crevicular fluid during initial orthodontic tooth movement. J Dent Res. 2003;82:1018-22. MMP-9 is responsible for cleavage of denatured collagen, i.e gelatin;⁶⁰60 Redlich M, Reichenberg E, Harari D, Zaks B, Shoshan S, Palmon A. The effect of mechanical force on mRNA levels of collagenase, collagen type I, and tissue inhibitors of metalloproteinases in gingivae of dogs. J Dent Res. 2001 Dec;80(12):2080-4. MMP-13 dissolves native fibrillar collagen; MMP-1 is an interstitial collagenase hydrolyzing mainly type III collagen,⁶¹61 Welgus HG, Jeffrey JJ, Eisen AZ. The collagen substrate specificity of human skin fibroblast collagenase. J Biol Chem. 1981 Sept 25;256(18):9511-5. and MMP-3 is responsible for activation of MMPs 8 and 9.⁶²62 Beklen A, Tüter G, Sorsa T, Hanemaaijer R, Virtanen I, Tervahartiala T, et al. Gingival tissue and crevicular fluid co-operation in adult periodontitis. J Dent Res. 2006 Jan;85(1):59-63. Hence peaks of MMP8 and MMP9/NGAL ratio at 14d¹⁷17 Canavarro C, Teles RP, Capelli Júnior J. Matrix metalloproteinases -1, -2, -3, -7, -8, -12, and -13 in gingival crevicular fluid during orthodontic tooth movement: a longitudinal randomized split-mouth study. Eur J Orthod .2013;35(5):652-8. and 72hr,¹³ respectively, occur subsequent to peak of MMP-3 in 1hr/24hr.¹⁷17 Canavarro C, Teles RP, Capelli Júnior J. Matrix metalloproteinases -1, -2, -3, -7, -8, -12, and -13 in gingival crevicular fluid during orthodontic tooth movement: a longitudinal randomized split-mouth study. Eur J Orthod .2013;35(5):652-8.^,²⁰20 Capelli J Jr, Kantarci A, Haffajee A, Teles RP, Fidel R Jr, Figueredo CM. Matrix metalloproteinases and chemokines in the gingival crevicular fluid during orthodontic tooth movement. Eur J Orthod. 2011;33(6):705-11. In vitro studies also support rise in MMPs in orthodontic forces, specifically MMP-1,2 mRNA and protein production in human gingival and pdl fibroblasts⁶³63 Nahm DS, Kim HJ, Mah J, Baek SH. In vitro expression of matrix metalloproteinase-1, tissue inhibitor of metalloproteinase- 1 and transforming growth factor-beta1 in human periodontal ligament fibroblasts. Eur J Orthod. 2004 Apr;26(2):129-35.^,⁶⁴64 Bolcato-Bellemin AL, Elkaim R, Abehsera A, Fausser JL, Haikel Y, Tenenbaum H. Expression of mRNAs encoding for alpha and beta integrin subunits, MMPs, and TIMPs in stretched human periodontal ligament and gingival fibroblasts. J Dent Res. 2000 Sep;79(9):1712-6. and MMP-1,2, 9 in gingival tissue of dogs.⁶⁰60 Redlich M, Reichenberg E, Harari D, Zaks B, Shoshan S, Palmon A. The effect of mechanical force on mRNA levels of collagenase, collagen type I, and tissue inhibitors of metalloproteinases in gingivae of dogs. J Dent Res. 2001 Dec;80(12):2080-4.

On the other hand, no significant change in MMP levels were seen in control teeth where no orthodontic force was applied.^17,22 This clearly supports MMPs as key mediators of remodeling in OTM.

MMPs are also shown to vary with site (tension and compression) in a time-dependent manner, as supported by in vitro models on pdl fibroblasts.^65,66 Current review showed an increase in MMP1,2 in 1-3hr on tension site (TS) of maxillary canine after activation of NiTi spring while in compression (CS), MMP1 increased at 1hr and MMP2 later, at 8hr.²²22 Cantarella G, Cantarella R, Caltabiano M, Risuglia N, Bernardini R, Leonardi R. Levels of matrix metalloproteinases 1 and 2 in human gingival crevicular fluid during initial tooth movement. Am J Orthod Dentofacial Orthop. 2006;130(5):568.e11-6. MMP-9 also increased from 4hr to 7d on compression site in another study.¹³13 Surlin P, Silosi I, Rauten AM, Cojocaru M, Foia L. Involvement of TSP1 and MMP9/NGAL in angiogenesis during orthodontic periodontal remodeling. Sci World J. 2014;2014:421029. This upsurge in levels indicate initial collagen turnover and disintegration of ECM on both tension and compression sites in initial phases of OTM.

Contrary to the MMPs, CS showed a significant increase in GCF levels of MMP inhibitors, TIMP-1 at 4hr and TIMP-2 after 7d during retraction of canines, coinciding with lag phase where tooth movement slows down.¹⁸18 Grant M, Wilson J, Rock P, Chapple I. Induction of cytokines, MMP9, TIMPs, RANKL and OPG during orthodontic tooth movement. Eur J Orthod. 2013;35(5):644-51.^,⁵⁰50 Saloom HF, Papageorgiou SN, Carpenter GH, Cobourne MT. Impact of obesity on orthodontic tooth movement in adolescents: a prospective clinical cohort study. J Dent Res. 2017;96(5):547-54. At TS, a significant increase in TIMP1 and 2 levels was seen at 4hr, 7d and 42d. This finding is in agreement with the results of a study by Bildt et al⁶⁷67 Bildt MM, Bloemen M, Kuijpers-Jagtman AM, Von den Hoff JW. Matrix metalloproteinases and tissue inhibitors of metalloproteinases in gingival crevicular fluid during orthodontic tooth movement. Eur J Orthod. 2009 Oct;31(5):529-35. where a continuous force with NiTi spring of 150cN was applied for retraction and an increase in MMP1 and TIMP1 was seen on pooled samples from resorption (corresponding to compression) and apposition side (tension) but no trace of TIMP2 was found. The mechanism of action of TIMP-1 stimulates release of MMP1,⁶⁸68 Clark IM, Powell LK, Cawston TE. Tissue inhibitor of metalloproteinases (TIMP-1) stimulates the secretion of collagenase from human skin fibroblasts. Biochem Biophys Res Commun. 1994 Sept 15;203(2):874-80. an interstitial collagenase, associated with normal tissue remodeling or stretch of pdl fibers, hydrolysing mainly type III collagen.⁶⁴64 Bolcato-Bellemin AL, Elkaim R, Abehsera A, Fausser JL, Haikel Y, Tenenbaum H. Expression of mRNAs encoding for alpha and beta integrin subunits, MMPs, and TIMPs in stretched human periodontal ligament and gingival fibroblasts. J Dent Res. 2000 Sep;79(9):1712-6. Also, TIMP-1 increases in smaller amounts on the site of compression, while retraction due to stimulation of bone resorption but in higher amounts on tension, it decreases bone resorption.⁶⁷67 Bildt MM, Bloemen M, Kuijpers-Jagtman AM, Von den Hoff JW. Matrix metalloproteinases and tissue inhibitors of metalloproteinases in gingival crevicular fluid during orthodontic tooth movement. Eur J Orthod. 2009 Oct;31(5):529-35. A study by Garlet et al.⁶⁹69 Garlet TP, Coelho U, Silva JS, Garlet GP. Cytokine expression pattern in compression and tension sides of the periodontal ligament during orthodontic tooth movement in humans . Eur J Oral Sci. 2007 Oct;115(5):355-62. provided evidence of greater expression of TIMP-1 mRNA on TS and MMP-1 mRNA on CS and TS of experimental teeth compared with the control.

Besides MMPs, histological studies on rats provide evidence of other enzymes for bone resorption predominant in CS in early phases of OTM followed by bone deposition in TS.^70,71 In accordance, the current review also shows resorptive enzyme -ACP in initial 3-5d of tooth movement.¹⁴ Few studies on retraction with continuous forces document an initial rise in ACP both on TS and CS with a peak in 14d⁴² and 21d.⁴⁶46 Arifyezdani A. Acid phosphatase activity in gingival crevicular fluid during human orthodontic tooth movement. Biomed Pharmacol J. 2015; 8(Spl. Edn):403-8. Initial resorption is followed by a late phase of bone deposition (7-14d) marked by an increase in bone formative ALP levels,^37,45 seen both in TS and CS of alveolar wall. Increase in ALP occurs by increasing the local concentration of phosphate ions after hydrolysis of phosphomonoester bonds, thus bone mineralisation. Highest serum ALP activity in humans has been correlated with greatest osteoblastic activity during growth spurts.⁷²72 Savic L, Savic D. Serum calcium and phosphorus concentration and alkaline phosphatase activity in healthy children during growth and development. Med Pregl. 2008 July-Aug;61(7-8):393-9.^,⁷³73 Christenson RH. Biochemical markers of bone metabolism: an overview. Clin Biochem. 1997;30:573-93. The current review has 17 studies evaluating ALP in association with type, site and magnitude of force. ALP levels increased at TS in continuous retraction forces by NiTi spring as well as in gradually increasing force from 50 cN to 150cN at 2wk, showing a predisposition towards bone deposition.⁹9 Alswafeeri H, ElKenany W, Mowafy M, Helmy M. Crevicular alkaline phosphatase activity during the application of two patterns of orthodontic forces. J Orthod. 2015;42(1):5-13. A study in rats supported osteoid deposition in the lacunae on TS in 80-120d.⁷⁴ The current review shows peak in ALP levels at 2wk on continuous force application of 150cN, 100g or 150g force⁹9 Alswafeeri H, ElKenany W, Mowafy M, Helmy M. Crevicular alkaline phosphatase activity during the application of two patterns of orthodontic forces. J Orthod. 2015;42(1):5-13.^,¹⁰10 Alfaqeeh SA, Anil S. Gingival crevicular fluid flow rate and alkaline phosphatase level as potential marker of active tooth movement. Oral Health Dent Manag. 2014 June;13(2):458-63.^,¹⁴14 Kulal R, Thomas B, Ravi MS, Shetty S. Enzymatic evaluation of gingival crevicular fluid in cleft palate patients during orthodontic treatment: a clinico-biochemical study. J Indian Soc Periodontol. 2013;17(3):319-23.^,²⁴24 Batra P, Kharbanda OP, Duggal R, Singh N, Parkash H. Alkaline phosphatase activity in gingival crevicular fluid during canine retraction. Orthod Craniofac Res. 2006;9(1):44-51.^,²⁸28 Perinetti G, Paolantonio M, Serra E, D'Archivio D, D'Ercole S, Festa F, et al. Longitudinal monitoring of subgingival colonization by Actinobacillus actinomycetemcomitans, and crevicular alkaline phosphatase and aspartate aminotransferase activities around orthodontically treated teeth. J Clin Periodontol 2004;31(1):60-7.^,⁴⁵45 Arifyezdani A. Alkaline phosphatase activity in gingival crevicular fluid: a diagnostic marker to assess human orthodontic tooth movement. Biomed Pharmacol J. 2015;8(Spl. Edn): 293-301., with greater levels on TS compared to CS. This is followed by fall in ALP levels corresponding to hyalinised tissue removal and initiation of post lag phase.⁹9 Alswafeeri H, ElKenany W, Mowafy M, Helmy M. Crevicular alkaline phosphatase activity during the application of two patterns of orthodontic forces. J Orthod. 2015;42(1):5-13.^,²⁴24 Batra P, Kharbanda OP, Duggal R, Singh N, Parkash H. Alkaline phosphatase activity in gingival crevicular fluid during canine retraction. Orthod Craniofac Res. 2006;9(1):44-51. Magnitude of force was another determinant of variation in ALP. Decrease in ALP levels seen at 1hr, 1d after intrusion by TMA spring is believed to be caused by heavy forces leading to a hyalinised zone.²⁵ Conversely, distalisation of molars with heavy cF of 250g³¹31 Tzannetou S, Efstratiadis S, Nicolay O, Grbic J, Lamster I. Interleukin-1 beta and beta-glucuronidase in gingival crevicular fluid from molars during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 1999;115(6):686-96. showing high ALP levels at both TS and CS and ALP levels greater in 150g than 100g force,³⁴34 Wahab RMA, Yamamoto R, Sintian A, Kasim NA, Abidin IZZ, Senafi S, et al. The effects of orthodontic forces during canine retraction using self- ligating brackets on gingival crevicular fluid enzyme activity, canine movement and root resorption. Sains Malaysiana. 2015;44(2):249-56. were attributed to extensive osteoblast recruitment on application of heavy forces.⁹ One study showing decreased ALP levels on both TS and CS of canine retraction with push coil spring was probably due to combination of bodily and tipping movement, which precludes pure compression and tension areas.³⁸38 Asma AAA, Rohaya MAW, Hisham ZAS. Crevicular alkaline phosphatase activity during orthodontic tooth movement: canine retraction stage. J Med Sci. 2008;8(3):228-33. ALP also varied with type of force: one study compared levels in Hycon^® screw with active tie-backs for retraction. A significant difference was seen at 3 and 4 wk of retraction with levels in Hycon screw group 260% higher after one half turn twice weekly activation, compared with 200% increase in active tie-back group.⁴⁹49 Kalha AS, Kachiwala VA, Govardhan SN, McLaughlin RP, Khurshaid SZ. Redefining orthodontic space closure: sequential repetitive loading of the periodontal ligament-a clinical study. World J Orthod. 2010;11(3):221-9. This may be ascribed to elastomeric force decay to 30-40% of original force in 3 weeks. Another study on maxillary expansion by hyrax followed by retention noticed fall in ALP levels on CS and TS till four weeks of activation, followed by peak at 1yr on TS, thus indicating bone apposition during retention period.⁵¹51 Delli Mauri A, Petrini M, Vitale D, Tecco S, Festa F, Barbato E, et al. Alkaline phosphatase level in gingival crevicular fluid during treatment with Quad-Helix. J Biol Regul Homeost Agents. 2015 Oct-Dec;29(4):1017-23.

Contrary to ALP, TRAP or ACP facilitates dissolution of bone minerals by forming a highly acidic extracellular environment and are potent osteoclast biomarkers expressed in areas of compression.⁷⁴74 Rody WJ Jr, King GJ, Gu G. Osteoclasts recruitment to sites of compression in orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2001 Nov;120(5):477-89. The present review supports rise in TRAP levels at CS more than TS to reach peak at 1wk,³³33 Karaduman B, Uraz A, Altan GN, Tuncer BB, Alkan O, Gönen S, et al. Changes of tumor necrosis factor-?, interleukin-10, and tartrate-resistant acid phosphatase 5b in the crevicular fluid in relation to orthodontic movement. Eur J Inflamm. 2015;13(1):3-13. 2wk¹¹ and 4-5wk.³⁴34 Wahab RMA, Yamamoto R, Sintian A, Kasim NA, Abidin IZZ, Senafi S, et al. The effects of orthodontic forces during canine retraction using self- ligating brackets on gingival crevicular fluid enzyme activity, canine movement and root resorption. Sains Malaysiana. 2015;44(2):249-56.^,³⁶36 Wahab RMA, Dasor MM, Senafi S, Abdullah AAA, Jemain AA, Kasim NA, et al. Crevicular tartrate resistant acid phosphatase activity and rate of tooth movement under different continuous force applications. African J Pharmacy Pharmacol. 2011;5(20):2213-9. This is supported by histochemical study by Casa et al,⁷⁵75 Casa MA, Faltin RM, Faltin K, Arana-Chavez VE. Root resorption on torqued human premolars shown by tartrate resistant acid phosphatase histochemistry and transmission electron microscopy. Angle Orthod. 2006 Nov;76(6):1015-21. suggestive of appearance of mononuclear TRAP positive cells on application of forces at 2wk and multinucleated TRAP positive cells at 3 and 4wk. Even ACP activity was maximum at 3d, followed by its reversal, explained by natal release of enzymes from surface of osteoclasts.¹⁴14 Kulal R, Thomas B, Ravi MS, Shetty S. Enzymatic evaluation of gingival crevicular fluid in cleft palate patients during orthodontic treatment: a clinico-biochemical study. J Indian Soc Periodontol. 2013;17(3):319-23. A secondary outcome of faster rate of OTM with minimal lateral and apical root resorption was noticed with higher levels of TRAP in 150g, compared with 100g force.³⁴34 Wahab RMA, Yamamoto R, Sintian A, Kasim NA, Abidin IZZ, Senafi S, et al. The effects of orthodontic forces during canine retraction using self- ligating brackets on gingival crevicular fluid enzyme activity, canine movement and root resorption. Sains Malaysiana. 2015;44(2):249-56.^,³⁶36 Wahab RMA, Dasor MM, Senafi S, Abdullah AAA, Jemain AA, Kasim NA, et al. Crevicular tartrate resistant acid phosphatase activity and rate of tooth movement under different continuous force applications. African J Pharmacy Pharmacol. 2011;5(20):2213-9.

The consummation of bone resorption occurs by resolution of organic matrix mediated by lysosomal cysteine protease cathepsin B that is increased 1d after application of 100-150g or 250g retraction force by E chain,²¹21 Rhee SH, Kang J, Nahm DS. Cystatins and cathepsin B during orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2009;135(1):99-105.^,³⁰30 Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Tripodi D, Femminella B, et al. Alkaline phosphatase activity in gingival crevicular fluid during human orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2002;122(5):548-56. while levels of inhibitor cystatin decreases in 1d.²¹21 Rhee SH, Kang J, Nahm DS. Cystatins and cathepsin B during orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2009;135(1):99-105. In association, plasminogen activator (t-PA) and its inhibitor (PAI) responsible for extravascular fibrinolysis, reach peak at 24hr only to fall later at 7d.²³23 Hoshino-Itoh J, Kurokawa A, Yamaguchi M, Kasai K. Levels of t-PA and PAI-2 in gingival crevicular fluid during orthodontic tooth movement in adults. Aust Orthod J. 2005;21(1):31-7.

AST is another cytoplasmic enzyme released in extracellular environment after cell membrane lysis following necrosis⁷⁶76 Williams DL, Marks V. Biochemistry in clinical practice. London: William Heinemann Medical Books;1983. and has been evaluated in 10 studies in the current SR. Peak levels of AST were seen at 1wk,¹¹11 Abdul Wahab RM, Abu Kasim N, Senafi S, Jemain AA, Zainol Abidin IZ, Shahidan MA, et al. Enzyme activity profiles and ELISA analysis of biomarkers from human saliva and gingival crevicular fluid during orthodontic tooth movement using self-ligating brackets. Oral Health Dent Manag. 2014 June;13(2):194-9.^,⁴⁰40 Rohaya MAW, Hisham ZAS, Khazlina K. Preliminary study of aspartate aminotransferase activity in gingival crevicular fluids during orthodontic tooth movement. J Applied Sci. 2009;9(7):1393-96.^,⁴¹41 Hassan KS, Alagl SA, Ali I. Periodontal status following self-ligature versus archwire ligation techniques in orthodontically treated patients: Clinical, microbiological and biochemical evaluation. Orthod Waves. 2010;69:164-70.^,⁵⁴54 Haq AU, Iqbal J, Hussain K, Munir A, Irfan S. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic tooth movement. APMC. 2017;11(2):149-53. 2wk,¹⁴14 Kulal R, Thomas B, Ravi MS, Shetty S. Enzymatic evaluation of gingival crevicular fluid in cleft palate patients during orthodontic treatment: a clinico-biochemical study. J Indian Soc Periodontol. 2013;17(3):319-23.^,⁴⁸48 Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Dolci M, Femminella B, et al. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic treatment. A controlled short-term longitudinal study. J Periodontol. 2003;74(2):145-52. and 4wk.²⁸28 Perinetti G, Paolantonio M, Serra E, D'Archivio D, D'Ercole S, Festa F, et al. Longitudinal monitoring of subgingival colonization by Actinobacillus actinomycetemcomitans, and crevicular alkaline phosphatase and aspartate aminotransferase activities around orthodontically treated teeth. J Clin Periodontol 2004;31(1):60-7.^,³⁹39 Rohaya MAW, Hisham ZAS, Khazlina K. The activity of aspartate aminotransferase during canine retraction (bodily tooth movement) in orthodontic treatment. J Med Sci. 2008;8:553-8. This may be explained on the basis of increase in AST activity for 14d due to hyalinization of pdl in compression zone, decreased later upon resolution of hyalinized area by macrophages.¹⁴14 Kulal R, Thomas B, Ravi MS, Shetty S. Enzymatic evaluation of gingival crevicular fluid in cleft palate patients during orthodontic treatment: a clinico-biochemical study. J Indian Soc Periodontol. 2013;17(3):319-23. The formation of hyalinised zone and cellular necrosis may cause higher levels on CS than TS in retraction cases³⁹39 Rohaya MAW, Hisham ZAS, Khazlina K. The activity of aspartate aminotransferase during canine retraction (bodily tooth movement) in orthodontic treatment. J Med Sci. 2008;8:553-8.^,⁴⁸48 Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Dolci M, Femminella B, et al. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic treatment. A controlled short-term longitudinal study. J Periodontol. 2003;74(2):145-52. and also in 150g force, compared to 100g.¹¹11 Abdul Wahab RM, Abu Kasim N, Senafi S, Jemain AA, Zainol Abidin IZ, Shahidan MA, et al. Enzyme activity profiles and ELISA analysis of biomarkers from human saliva and gingival crevicular fluid during orthodontic tooth movement using self-ligating brackets. Oral Health Dent Manag. 2014 June;13(2):194-9.^,³⁴34 Wahab RMA, Yamamoto R, Sintian A, Kasim NA, Abidin IZZ, Senafi S, et al. The effects of orthodontic forces during canine retraction using self- ligating brackets on gingival crevicular fluid enzyme activity, canine movement and root resorption. Sains Malaysiana. 2015;44(2):249-56. But, such sporadic evidence could not be definitive for site predilection. Rather this enzyme has been associated more with destruction of gingival tissues in experimental and chronic periodontitis⁷⁷77 McCulloch CA. Host enzymes in gingival crevicular fluid as diagnostic indicators of periodontitis (Review). J Clin Periodontol. 1994 Aug;21(7):497-506. and subgingival colonization with arch wire ligation⁴¹41 Hassan KS, Alagl SA, Ali I. Periodontal status following self-ligature versus archwire ligation techniques in orthodontically treated patients: Clinical, microbiological and biochemical evaluation. Orthod Waves. 2010;69:164-70. than orthodontic force application.

The current review has also monitored LDH, an enzyme released from cytoplasm to extracellular space after cell death in gingivitis or periodontitis⁷⁸78 Yost KG, Mallatt ME, Liebman J. Interproximal gingivitis and plaque reduction by four interdental products. J Clin Dent. 2006;17(3):79-83. as well as in orthodontic treatment.¹⁶16 Bolamperti L, Montanari P, Levrini L, Macchi A, Tagliabue A, Caprioglio A. Tissue response during self-ligating treatment. Prog Orthod. 2012;13(2):109-16.^,²⁶26 Perinetti G, Serra E, Paolantonio M, Bruè C, Meo SD, Filippi MR, et al. Lactate dehydrogenase activity in human gingival crevicular fluid during orthodontic treatment: a controlled, short-term longitudinal study. J Periodontol. 2005;76(3):411-7. Variation in LDH levels were recorded with type, magnitude and direction of application of force. Continuous force of 125g with NiTi spring showed increase in levels at 7d to peak at 14d,²⁶26 Perinetti G, Serra E, Paolantonio M, Bruè C, Meo SD, Filippi MR, et al. Lactate dehydrogenase activity in human gingival crevicular fluid during orthodontic treatment: a controlled, short-term longitudinal study. J Periodontol. 2005;76(3):411-7. 21d¹⁹19 Alfaqeeh SA, Anil S. Lactate dehydrogenase activity in gingival crevicular fluid as a marker in orthodontic tooth movement. Open Dent J. 2011;5:105-9. and 28d,⁴⁸48 Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Dolci M, Femminella B, et al. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic treatment. A controlled short-term longitudinal study. J Periodontol. 2003;74(2):145-52. but remained higher in CS than TS at 1.5 N,³⁵35 Ariffin SHZ, Kasim NA, Wahab RMA, Jemain AA. Lactate dehydrogenase activity during tooth movement under 1.0 N and 1.5 N continuous force applications. Sains Malaysiana. 2013;42(1):99-105. thus favouring its release after cell death. Timing of increase varied with force level, with an early increase seen at 2wk in heavy force of 250g applied for molar distalisation.²⁶26 Perinetti G, Serra E, Paolantonio M, Bruè C, Meo SD, Filippi MR, et al. Lactate dehydrogenase activity in human gingival crevicular fluid during orthodontic treatment: a controlled, short-term longitudinal study. J Periodontol. 2005;76(3):411-7. compared with rise in 3wk in 125g force.¹⁹19 Alfaqeeh SA, Anil S. Lactate dehydrogenase activity in gingival crevicular fluid as a marker in orthodontic tooth movement. Open Dent J. 2011;5:105-9.^,⁴⁷47 Lakshmanan P, Sathya PB, Dilip S, Srinivas S. Evaluation of lactate dehydrogenase levels in gingival crevicular fluid during orthodontic tooth movement an in-vivo study. Res J Pharmaceutical Biol Chem Sci. 2015;6(5):877-88. However no significant difference in LDH levels could be correlated to high friction between self-ligating brackets and thermoelastic or superelastic Nitinol wires, as the forces produced by frictional resistance are insufficient for LDH release.¹⁶16 Bolamperti L, Montanari P, Levrini L, Macchi A, Tagliabue A, Caprioglio A. Tissue response during self-ligating treatment. Prog Orthod. 2012;13(2):109-16. One study supporting greater LDH levels in teeth undergoing retraction compared with controls was excluded from this review because of its cross-sectional study design.⁷⁹ It supported LDH as a sensitive marker of the pdl metabolism changes during OTM.

Other inflammatory mediators like MPO and βG were also evaluated in this review. MPO released from PMNLs (polymorphonuclear leukocytes) is a sensitive marker for inflammation and pain associated to OTM and showed an early increase at 2hr.^{8,12,50,52,53} In cases of alignment, the levels of MPO increase from baseline to 1hr to 1d till completion of alignment, correlating it with inflammation caused by NiTi wire alignment.⁵⁰ Studies on MPO also supported superelastic NiTi wires as best alignment wires, giving low continuous force and rapid tooth movement, showing higher MPO levels at 2hr, compared with heat-activated NiTi or multistranded NiTi or stainless steel wires.⁵²52 Fatima A, Talapaneni AK, Saleh A, Sana S, Hussain A. An evaluation and comparison of myeloperoxidase enzymatic activity during initial orthodontic alignment: an in vivo study. J Orthod. 2017 Sept;44(3):169-173.^,⁵³53 Bhasin V, Singh M, Goutam M, Singh S, Nigam AS, Joshi A. Comparative evaluation of myeloperoxidase enzymatic activity in gingival crevicular fluid of subjects having orthodontic treatment by different aligning arch wires. J Contemp Dent Pract. 2017;18(10):977-80. Studies also mentioned increase in lysosomal enzyme, βG released from PMNLs after 14d of heavy interrupted force for mid-palatal hyrax expansion in adolescents.⁷7 Tzannetou S, Efstratiadis S, Nicolay O, Grbic J andLamster I. Comparison of levels of inflammatory mediators IL-1beta and betaG in gingival crevicular fluid from molars, premolars, and incisors during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 2008;133(5):699-707.^,³¹31 Tzannetou S, Efstratiadis S, Nicolay O, Grbic J, Lamster I. Interleukin-1 beta and beta-glucuronidase in gingival crevicular fluid from molars during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 1999;115(6):686-96. However, the levels remained high till 28d in retention, probably due to elastic recoil of stretched supracrestal gingival fibers.⁷7 Tzannetou S, Efstratiadis S, Nicolay O, Grbic J andLamster I. Comparison of levels of inflammatory mediators IL-1beta and betaG in gingival crevicular fluid from molars, premolars, and incisors during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 2008;133(5):699-707.^,³¹31 Tzannetou S, Efstratiadis S, Nicolay O, Grbic J, Lamster I. Interleukin-1 beta and beta-glucuronidase in gingival crevicular fluid from molars during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 1999;115(6):686-96.

The risk of bias assessment in QAI though indicated all studies as moderately or highly sensitive, revealed certain strengths and weaknesses of variable study designs (Table 7). While the objectives of the studies, selection criteria and orthodontic mechanics were generally clear, they strikingly lacked sample size calculation with only one study indicating the same.⁹ The authors took 5 as the sample size for inclusion, based on statistician’s advice. Randomization of experimental teeth/ side / patients falling into study and control group have been clearly stated in only 21 out of 48 studies, suggesting substantial bias in all studies. The present SR deals with biomarker evaluation in GCF, hence the GCF handling characteristics have been adequate in all studies. However, the specification of time, temperature and humidity at the time of GCF collection was a major shortfall, with only four studies mentioning it. The statistical significance of the results, wherever applicable, have been stated in all the studies, but none of the studies mentioned dropouts or confounders, which might influence the results.

Thumbnail

Table 7
Results of quality assessment of 48 studies for inclusion of studies in the review

Despite the various shortcomings noticed in the study designs, the current evidence has generated ample evidence related to enzymes in OTM and has also opened new arena for future research in this direction.

Perhaps a most exciting area of research will involve biological basis of tooth movement with different ligation modes of brackets. Further studies could be conducted with LDH as marker for high frictional resistance in different combinations of brackets and wires, as only single study in this SR found no significant change in LDH in initial OTM with self-ligating brackets and superelastic or thermoactive archwire. Another split-mouth study correlating biomarker level with microbial colonization in different ligation modes showed a significantly greater level of AST in arch wire ligation than self-ligation, associated with greater microbial count.

An interesting correlation of MPO with pain was established with an early increase in MPO within 2hr of force application, coinciding with initial pain incidence in orthodontic patients. βG has been explored for its association with the most suitable wires for alignment and could be explored further in different types and magnitudes of forces.

Based on similarity between peri-implant fluid (PIMF) and GCF, the mediators studied in GCF could also be evaluated in PICF to assess stability of contemporary orthodontic anchorage devices, micro-implants, as has been suggested by study of interleukin 1β in PIMF.⁸⁰80 Monga N, Chaurasia S, Kharbanda OP, Duggal R, Rajeswari MR. A study of interleukin 1? levels in peri-mini screw crevicular fluid (PMCF). Prog Orthod. 2014;15(1):30-35.

Despite the heterogeneity in study design and categories of enzymes studied in literature, this SR provides an essential overview of the mechanism by which enzymes play a role in bone apposition, resorption as well as ECM degradation. The current SR also correlates mediator levels in GCF with phases of OTM at different magnitudes and types of forces and also ligation modes. It goes a step further in suggesting the potential areas of research in this field, based on individual studies designed for associations of mediator levels with ideal orthodontic force magnitudes, method of ligation and periodontal status, thus setting a direct implication in clinical practice.

CONCLUSIONS

Orthodontic force induces change in levels of multiple enzymes detectable in GCF. These are:
- a) cytoplasmic enzymes released in extracellular environment after cell lysis (LDH, AST), b) Inflammatory markers released from PMNs (MPO, βG), c) enzymes involved in bone and tissue remodelling by bone resorption (TRAP, ACP), d) bone apposition (ALP) or dissolution of organic matrix (Cp, Cys, tPA, PAI) and e) various categories of MMPs responsible for degradation of ECM (MMP1, 2, 3, 8, 9, 13).
Compression sites showed early increase in levels of MMP1, MMP2, TIMP1, MMP9 between 1-4hr, and late peak in TIMP2, TRAP, AST after 7d, 4-5wk and 8-12wk, respectively.
Tension sites showed significant increase in ALP after 7d, MMP1 between 1-3hr and TIMP 1 and 2 levels at 4hr, 7d and 42d.
Distinction between TS and CS could be made with levels of TRAP, AST, LDH, MMP9, being greater on CS than TS, and ALP greater on TS.
ALP, TRAP levels were greater in 150g force than 100g force. An early rise in AST levels was seen in 150g force at 3 and 4wk, as compared to 100g force at 4 and 5 wk.
Mechanical stress with continuous force of NiTi spring causes increase in MMPs 1, 3 in 24hr in CS and of ALP as early as 7d in TS.
No significant association between levels of MMP-9 or AST and growth status could be established as adult and adolescents, gave no significant difference in levels.

REFERENCES

¹
Meeran NA. Cellular response within the periodontal ligament on application of orthodontic forces. J Indian Soc Periodontol. 2013;17(1):16-20.
²
Krishnan V, Davidovitch Z. Cellular, molecular, and tissue-level reactions to orthodontic force. Am J Orthod Dentofacial Orthop. 2006 Apr;129(4):469.e1-32.
³
Alhadlaq AM. Biomarkers of orthodontic tooth movement in gingival crevicular fluid: a systematic review. J Contemp Dent Pract. 2015;16(7):578-87.
⁴
Apuzzo F, Cappabianca S, Ciavarella D, Monsurrò A, Silvestrini-Biavati A, Perillo L. Biomarkers of periodontal tissue remodeling during orthodontic tooth movement in mice and men: overview and clinical relevance. Sci World J. 2013 Apr 23;2013:105873.
⁵
Lilja E, Lindskog S, Hammarström L. Histochemistry of enzymes associated with tissue degradation incident to orthodontic tooth movement. Am J Orthod. 1983;83(1):62-75.
⁶
Kapoor P, Kharbanda OP, Monga N, Miglani R, Kapila S. Effect of orthodontic forces on cytokine and receptor levels in gingival crevicular fluid: a systematic review. Prog Orthod. 2014 Dec 9;15:65.
⁷
Tzannetou S, Efstratiadis S, Nicolay O, Grbic J andLamster I. Comparison of levels of inflammatory mediators IL-1beta and betaG in gingival crevicular fluid from molars, premolars, and incisors during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 2008;133(5):699-707.
⁸
Marcaccini AM, Amato PA, Leão FV, Gerlach RF, Ferreira JT. Myeloperoxidase activity is increased in gingival crevicular fluid and whole saliva after fixed orthodontic appliance activation. Am J Orthod Dentofacial Orthop. 2010 Nov;138(5):613-6.
⁹
Alswafeeri H, ElKenany W, Mowafy M, Helmy M. Crevicular alkaline phosphatase activity during the application of two patterns of orthodontic forces. J Orthod. 2015;42(1):5-13.
¹⁰
Alfaqeeh SA, Anil S. Gingival crevicular fluid flow rate and alkaline phosphatase level as potential marker of active tooth movement. Oral Health Dent Manag. 2014 June;13(2):458-63.
¹¹
Abdul Wahab RM, Abu Kasim N, Senafi S, Jemain AA, Zainol Abidin IZ, Shahidan MA, et al. Enzyme activity profiles and ELISA analysis of biomarkers from human saliva and gingival crevicular fluid during orthodontic tooth movement using self-ligating brackets. Oral Health Dent Manag. 2014 June;13(2):194-9.
¹²
Navarro-Palacios A, García-López E, Meza-Rios A, Armendariz-Borunda J, Sandoval-Rodríguez A. Myeloperoxidase enzymatic activity is increased in patients with different levels of dental crowding after initial orthodontic activation. Am J Orthod Dentofacial Orthop. 2014 July;146(1):92-7.
¹³
Surlin P, Silosi I, Rauten AM, Cojocaru M, Foia L. Involvement of TSP1 and MMP9/NGAL in angiogenesis during orthodontic periodontal remodeling. Sci World J. 2014;2014:421029.
¹⁴
Kulal R, Thomas B, Ravi MS, Shetty S. Enzymatic evaluation of gingival crevicular fluid in cleft palate patients during orthodontic treatment: a clinico-biochemical study. J Indian Soc Periodontol. 2013;17(3):319-23.
¹⁵
Rody WJ Jr, Wijegunasinghe M, Wiltshire WA, Dufault B. Differences in the gingival crevicular fluid composition between adults and adolescents undergoing orthodontic treatment. Angle Orthod. 2014;84(1):120-6.
¹⁶
Bolamperti L, Montanari P, Levrini L, Macchi A, Tagliabue A, Caprioglio A. Tissue response during self-ligating treatment. Prog Orthod. 2012;13(2):109-16.
¹⁷
Canavarro C, Teles RP, Capelli Júnior J. Matrix metalloproteinases -1, -2, -3, -7, -8, -12, and -13 in gingival crevicular fluid during orthodontic tooth movement: a longitudinal randomized split-mouth study. Eur J Orthod .2013;35(5):652-8.
¹⁸
Grant M, Wilson J, Rock P, Chapple I. Induction of cytokines, MMP9, TIMPs, RANKL and OPG during orthodontic tooth movement. Eur J Orthod. 2013;35(5):644-51.
¹⁹
Alfaqeeh SA, Anil S. Lactate dehydrogenase activity in gingival crevicular fluid as a marker in orthodontic tooth movement. Open Dent J. 2011;5:105-9.
²⁰
Capelli J Jr, Kantarci A, Haffajee A, Teles RP, Fidel R Jr, Figueredo CM. Matrix metalloproteinases and chemokines in the gingival crevicular fluid during orthodontic tooth movement. Eur J Orthod. 2011;33(6):705-11.
²¹
Rhee SH, Kang J, Nahm DS. Cystatins and cathepsin B during orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2009;135(1):99-105.
²²
Cantarella G, Cantarella R, Caltabiano M, Risuglia N, Bernardini R, Leonardi R. Levels of matrix metalloproteinases 1 and 2 in human gingival crevicular fluid during initial tooth movement. Am J Orthod Dentofacial Orthop. 2006;130(5):568.e11-6.
²³
Hoshino-Itoh J, Kurokawa A, Yamaguchi M, Kasai K. Levels of t-PA and PAI-2 in gingival crevicular fluid during orthodontic tooth movement in adults. Aust Orthod J. 2005;21(1):31-7.
²⁴
Batra P, Kharbanda OP, Duggal R, Singh N, Parkash H. Alkaline phosphatase activity in gingival crevicular fluid during canine retraction. Orthod Craniofac Res. 2006;9(1):44-51.
²⁵
Isik F, Sayinsu K, Arun T, Unlüçerçi Y. Bone marker levels in gingival crevicular fluid during orthodontic intrusive tooth movement: a preliminary study. J Contemp Dent Pract. 2015;6(2):27-35.
²⁶
Perinetti G, Serra E, Paolantonio M, Bruè C, Meo SD, Filippi MR, et al. Lactate dehydrogenase activity in human gingival crevicular fluid during orthodontic treatment: a controlled, short-term longitudinal study. J Periodontol. 2005;76(3):411-7.
²⁷
Ingman T, Apajalahti S, Mäntylä P, Savolainen P, Sorsa T. Matrix metalloproteinase-1 and -8 in gingival crevicular fluid during orthodontic tooth movement: a pilot study during 1 month of follow-up after fixed appliance activation. Eur J Orthod. 2005;27(2):202-7.
²⁸
Perinetti G, Paolantonio M, Serra E, D'Archivio D, D'Ercole S, Festa F, et al. Longitudinal monitoring of subgingival colonization by Actinobacillus actinomycetemcomitans, and crevicular alkaline phosphatase and aspartate aminotransferase activities around orthodontically treated teeth. J Clin Periodontol 2004;31(1):60-7.
²⁹
Sugiyama Y, Yamaguchi M, Kanekawa M, Yoshii M, Nozoe T, Nogimura A, Kasai K. The level of cathepsin B in gingival crevicular fluid during human orthodontic tooth movement. Eur J Orthod. 2003;25(1):71-6.
³⁰
Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Tripodi D, Femminella B, et al. Alkaline phosphatase activity in gingival crevicular fluid during human orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2002;122(5):548-56.
³¹
Tzannetou S, Efstratiadis S, Nicolay O, Grbic J, Lamster I. Interleukin-1 beta and beta-glucuronidase in gingival crevicular fluid from molars during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 1999;115(6):686-96.
³²
Uematsu S, Mogi M, Deguchi T. Interleukin (IL)-1 beta, IL-6, tumor necrosis factor-alpha, epidermal growth factor, and beta 2-microglobulin levels are elevated in gingival crevicular fluid during human orthodontic tooth movement. J Dent Res. 1996;75(1):562-7.
³³
Karaduman B, Uraz A, Altan GN, Tuncer BB, Alkan O, Gönen S, et al. Changes of tumor necrosis factor-?, interleukin-10, and tartrate-resistant acid phosphatase 5b in the crevicular fluid in relation to orthodontic movement. Eur J Inflamm. 2015;13(1):3-13.
³⁴
Wahab RMA, Yamamoto R, Sintian A, Kasim NA, Abidin IZZ, Senafi S, et al. The effects of orthodontic forces during canine retraction using self- ligating brackets on gingival crevicular fluid enzyme activity, canine movement and root resorption. Sains Malaysiana. 2015;44(2):249-56.
³⁵
Ariffin SHZ, Kasim NA, Wahab RMA, Jemain AA. Lactate dehydrogenase activity during tooth movement under 1.0 N and 1.5 N continuous force applications. Sains Malaysiana. 2013;42(1):99-105.
³⁶
Wahab RMA, Dasor MM, Senafi S, Abdullah AAA, Jemain AA, Kasim NA, et al. Crevicular tartrate resistant acid phosphatase activity and rate of tooth movement under different continuous force applications. African J Pharmacy Pharmacol. 2011;5(20):2213-9.
³⁷
Abdullah AAA, Wahab RMA, Ariffin SHBZ. Pattern of crevicular alkaline phosphatase during orthodontic tooth movement: leveling and alignment stage. Sains Malaysiana. 2011;40(10):1147-51.
³⁸
Asma AAA, Rohaya MAW, Hisham ZAS. Crevicular alkaline phosphatase activity during orthodontic tooth movement: canine retraction stage. J Med Sci. 2008;8(3):228-33.
³⁹
Rohaya MAW, Hisham ZAS, Khazlina K. The activity of aspartate aminotransferase during canine retraction (bodily tooth movement) in orthodontic treatment. J Med Sci. 2008;8:553-8.
⁴⁰
Rohaya MAW, Hisham ZAS, Khazlina K. Preliminary study of aspartate aminotransferase activity in gingival crevicular fluids during orthodontic tooth movement. J Applied Sci. 2009;9(7):1393-96.
⁴¹
Hassan KS, Alagl SA, Ali I. Periodontal status following self-ligature versus archwire ligation techniques in orthodontically treated patients: Clinical, microbiological and biochemical evaluation. Orthod Waves. 2010;69:164-70.
⁴²
Farahani M, Safavi MS, Dianat O, Tusi SK, Younessian F. Acid and alkaline phosphatase levels in gcf during orthodontic tooth movement. J Dent Shiraz Univ Med Sci. 2015;16(3 Suppl): 237-45.
⁴³
Jeyraj Y, Katta AK, Vannala V, Lokanathan D, Reddy SN, Rajasigamani K. Estimation of alkaline phosphatase in the gingival crevicular fluid during orthodontic tooth movement in premolar extraction cases to predict therapeutic progression. J Nat SciBiolMed. 2015;6(2):343-6.
⁴⁴
Perinetti G, D'Apuzzo F, Contardo L, Primozic J, Rupel K, Perillo L. Gingival crevicular fluid alkaline phosphate activity during the retention phase of maxillary expansion in prepubertal subjects: A split-mouth longitudinal study. Am J Orthod Dentofacial Orthop. 2015 July;148(1):90-6.
⁴⁵
Arifyezdani A. Alkaline phosphatase activity in gingival crevicular fluid: a diagnostic marker to assess human orthodontic tooth movement. Biomed Pharmacol J. 2015;8(Spl. Edn): 293-301.
⁴⁶
Arifyezdani A. Acid phosphatase activity in gingival crevicular fluid during human orthodontic tooth movement. Biomed Pharmacol J. 2015; 8(Spl. Edn):403-8.
⁴⁷
Lakshmanan P, Sathya PB, Dilip S, Srinivas S. Evaluation of lactate dehydrogenase levels in gingival crevicular fluid during orthodontic tooth movement an in-vivo study. Res J Pharmaceutical Biol Chem Sci. 2015;6(5):877-88.
⁴⁸
Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Dolci M, Femminella B, et al. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic treatment. A controlled short-term longitudinal study. J Periodontol. 2003;74(2):145-52.
⁴⁹
Kalha AS, Kachiwala VA, Govardhan SN, McLaughlin RP, Khurshaid SZ. Redefining orthodontic space closure: sequential repetitive loading of the periodontal ligament-a clinical study. World J Orthod. 2010;11(3):221-9.
⁵⁰
Saloom HF, Papageorgiou SN, Carpenter GH, Cobourne MT. Impact of obesity on orthodontic tooth movement in adolescents: a prospective clinical cohort study. J Dent Res. 2017;96(5):547-54.
⁵¹
Delli Mauri A, Petrini M, Vitale D, Tecco S, Festa F, Barbato E, et al. Alkaline phosphatase level in gingival crevicular fluid during treatment with Quad-Helix. J Biol Regul Homeost Agents. 2015 Oct-Dec;29(4):1017-23.
⁵²
Fatima A, Talapaneni AK, Saleh A, Sana S, Hussain A. An evaluation and comparison of myeloperoxidase enzymatic activity during initial orthodontic alignment: an in vivo study. J Orthod. 2017 Sept;44(3):169-173.
⁵³
Bhasin V, Singh M, Goutam M, Singh S, Nigam AS, Joshi A. Comparative evaluation of myeloperoxidase enzymatic activity in gingival crevicular fluid of subjects having orthodontic treatment by different aligning arch wires. J Contemp Dent Pract. 2017;18(10):977-80.
⁵⁴
Haq AU, Iqbal J, Hussain K, Munir A, Irfan S. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic tooth movement. APMC. 2017;11(2):149-53.
⁵⁵
Lamster IB, Hartley LJ, Vogel RI. Development of a biochemical profile for gingival crevicular fluid. Methodological considerations and evaluation of collagen-degrading and ground substance degrading enzyme activity during experimental gingivitis. J Periodontol. 1985 Nov;56 Suppl 11S:13-21.
⁵⁶
Burstone CJ. The biomechanics of tooth movement. In: Kraus BS, Riedel RA, editors. Vistas in Orthodontics. Philadelphia: Lea & Febiger; 1962. p. 197-213.
⁵⁷
Pilon JJ, Kuijpers-Jagtman AM, Maltha JC. Magnitude of orthodontic forces and rate of bodily tooth movement: an experimental study in beagle dogs. Am J Orthod Dentofacial Orthop. 1996 Jul;110(1):16-23.
⁵⁸
van Leeuwen EJ, Maltha JC, Kuijpers-Jagtman AM. Tooth movement with light continuous and discontinuous forces in beagle dogs. Eur J Oral Sci. 1999 Dec;107(6):468-74.
⁵⁹
Apajalahti S, Sorsa T, Railavo S, Ingman T. The in vivo levels of matrix metalloproteinase-1 and -8 in gingival crevicular fluid during initial orthodontic tooth movement. J Dent Res. 2003;82:1018-22.
⁶⁰
Redlich M, Reichenberg E, Harari D, Zaks B, Shoshan S, Palmon A. The effect of mechanical force on mRNA levels of collagenase, collagen type I, and tissue inhibitors of metalloproteinases in gingivae of dogs. J Dent Res. 2001 Dec;80(12):2080-4.
⁶¹
Welgus HG, Jeffrey JJ, Eisen AZ. The collagen substrate specificity of human skin fibroblast collagenase. J Biol Chem. 1981 Sept 25;256(18):9511-5.
⁶²
Beklen A, Tüter G, Sorsa T, Hanemaaijer R, Virtanen I, Tervahartiala T, et al. Gingival tissue and crevicular fluid co-operation in adult periodontitis. J Dent Res. 2006 Jan;85(1):59-63.
⁶³
Nahm DS, Kim HJ, Mah J, Baek SH. In vitro expression of matrix metalloproteinase-1, tissue inhibitor of metalloproteinase- 1 and transforming growth factor-beta1 in human periodontal ligament fibroblasts. Eur J Orthod. 2004 Apr;26(2):129-35.
⁶⁴
Bolcato-Bellemin AL, Elkaim R, Abehsera A, Fausser JL, Haikel Y, Tenenbaum H. Expression of mRNAs encoding for alpha and beta integrin subunits, MMPs, and TIMPs in stretched human periodontal ligament and gingival fibroblasts. J Dent Res. 2000 Sep;79(9):1712-6.
⁶⁵
He Y, Macarak EJ, Korostoff JM, Howard PS. Compression and tension: differential effects on matrix accumulation by periodontal ligament fibroblasts in vitro. Connect Tissue Res. 2004;45(1):28-39.
⁶⁶
Takahashi I, Onodera K, Nishimura M, Mitnai H, Sasano Y, Mitani H. Expression of genes for gelatinases and tissue inhibitors of metalloproteinases in periodontal tissues during orthodontic tooth movement. J Mol Histol. 2006 Nov;37(8-9):333-42.
⁶⁷
Bildt MM, Bloemen M, Kuijpers-Jagtman AM, Von den Hoff JW. Matrix metalloproteinases and tissue inhibitors of metalloproteinases in gingival crevicular fluid during orthodontic tooth movement. Eur J Orthod. 2009 Oct;31(5):529-35.
⁶⁸
Clark IM, Powell LK, Cawston TE. Tissue inhibitor of metalloproteinases (TIMP-1) stimulates the secretion of collagenase from human skin fibroblasts. Biochem Biophys Res Commun. 1994 Sept 15;203(2):874-80.
⁶⁹
Garlet TP, Coelho U, Silva JS, Garlet GP. Cytokine expression pattern in compression and tension sides of the periodontal ligament during orthodontic tooth movement in humans . Eur J Oral Sci. 2007 Oct;115(5):355-62.
⁷⁰
Keeling SD, King GJ, McCoy EA, Valdez M. Serum and alveolar bone phosphatase changes reflect remodeling during orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 1993 Apr;103(4):320-6.
⁷¹
Whyte MP. Hypophosphatasia and the role of alkaline phosphatase in skeletal mineralization. Endocr Rev. 1994 Aug;15(4):439-61.
⁷²
Savic L, Savic D. Serum calcium and phosphorus concentration and alkaline phosphatase activity in healthy children during growth and development. Med Pregl. 2008 July-Aug;61(7-8):393-9.
⁷³
Christenson RH. Biochemical markers of bone metabolism: an overview. Clin Biochem. 1997;30:573-93.
⁷⁴
Rody WJ Jr, King GJ, Gu G. Osteoclasts recruitment to sites of compression in orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2001 Nov;120(5):477-89.
⁷⁵
Casa MA, Faltin RM, Faltin K, Arana-Chavez VE. Root resorption on torqued human premolars shown by tartrate resistant acid phosphatase histochemistry and transmission electron microscopy. Angle Orthod. 2006 Nov;76(6):1015-21.
⁷⁶
Williams DL, Marks V. Biochemistry in clinical practice. London: William Heinemann Medical Books;1983.
⁷⁷
McCulloch CA. Host enzymes in gingival crevicular fluid as diagnostic indicators of periodontitis (Review). J Clin Periodontol. 1994 Aug;21(7):497-506.
⁷⁸
Yost KG, Mallatt ME, Liebman J. Interproximal gingivitis and plaque reduction by four interdental products. J Clin Dent. 2006;17(3):79-83.
⁷⁹
Serra E, Perinetti G, D'Attilio M, Cordella C, Paolantonio M, Festa F, et al. Lactate dehydrogenase activity in gingival crevicular fluid during orthodontic treatment. Am J Orthod Dentofacial Orthop. 2003 Aug;124(2):206-11.
⁸⁰
Monga N, Chaurasia S, Kharbanda OP, Duggal R, Rajeswari MR. A study of interleukin 1? levels in peri-mini screw crevicular fluid (PMCF). Prog Orthod. 2014;15(1):30-35.

»
The authors report no commercial, proprietary or financial interest in the products or companies described in this article.

Publication Dates

Publication in this collection
20 May 2019
Date of issue
Mar-Apr 2019

History

Received
17 July 2018
Accepted
03 Nov 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Meeran NA. Cellular response within the periodontal ligament on application of orthodontic forces. J Indian Soc Periodontol. 2013;17(1):16-20.

[2] ²
Krishnan V, Davidovitch Z. Cellular, molecular, and tissue-level reactions to orthodontic force. Am J Orthod Dentofacial Orthop. 2006 Apr;129(4):469.e1-32.

[3] ³
Alhadlaq AM. Biomarkers of orthodontic tooth movement in gingival crevicular fluid: a systematic review. J Contemp Dent Pract. 2015;16(7):578-87.

[4] ⁴
Apuzzo F, Cappabianca S, Ciavarella D, Monsurrò A, Silvestrini-Biavati A, Perillo L. Biomarkers of periodontal tissue remodeling during orthodontic tooth movement in mice and men: overview and clinical relevance. Sci World J. 2013 Apr 23;2013:105873.

[5] ⁵
Lilja E, Lindskog S, Hammarström L. Histochemistry of enzymes associated with tissue degradation incident to orthodontic tooth movement. Am J Orthod. 1983;83(1):62-75.

[6] ⁶
Kapoor P, Kharbanda OP, Monga N, Miglani R, Kapila S. Effect of orthodontic forces on cytokine and receptor levels in gingival crevicular fluid: a systematic review. Prog Orthod. 2014 Dec 9;15:65.

[7] ⁷
Tzannetou S, Efstratiadis S, Nicolay O, Grbic J andLamster I. Comparison of levels of inflammatory mediators IL-1beta and betaG in gingival crevicular fluid from molars, premolars, and incisors during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 2008;133(5):699-707.

[8] ⁸
Marcaccini AM, Amato PA, Leão FV, Gerlach RF, Ferreira JT. Myeloperoxidase activity is increased in gingival crevicular fluid and whole saliva after fixed orthodontic appliance activation. Am J Orthod Dentofacial Orthop. 2010 Nov;138(5):613-6.

[9] ⁹
Alswafeeri H, ElKenany W, Mowafy M, Helmy M. Crevicular alkaline phosphatase activity during the application of two patterns of orthodontic forces. J Orthod. 2015;42(1):5-13.

[10] ¹⁰
Alfaqeeh SA, Anil S. Gingival crevicular fluid flow rate and alkaline phosphatase level as potential marker of active tooth movement. Oral Health Dent Manag. 2014 June;13(2):458-63.

[11] ¹¹
Abdul Wahab RM, Abu Kasim N, Senafi S, Jemain AA, Zainol Abidin IZ, Shahidan MA, et al. Enzyme activity profiles and ELISA analysis of biomarkers from human saliva and gingival crevicular fluid during orthodontic tooth movement using self-ligating brackets. Oral Health Dent Manag. 2014 June;13(2):194-9.

[12] ¹²
Navarro-Palacios A, García-López E, Meza-Rios A, Armendariz-Borunda J, Sandoval-Rodríguez A. Myeloperoxidase enzymatic activity is increased in patients with different levels of dental crowding after initial orthodontic activation. Am J Orthod Dentofacial Orthop. 2014 July;146(1):92-7.

[13] ¹³
Surlin P, Silosi I, Rauten AM, Cojocaru M, Foia L. Involvement of TSP1 and MMP9/NGAL in angiogenesis during orthodontic periodontal remodeling. Sci World J. 2014;2014:421029.

[14] ¹⁴
Kulal R, Thomas B, Ravi MS, Shetty S. Enzymatic evaluation of gingival crevicular fluid in cleft palate patients during orthodontic treatment: a clinico-biochemical study. J Indian Soc Periodontol. 2013;17(3):319-23.

[15] ¹⁵
Rody WJ Jr, Wijegunasinghe M, Wiltshire WA, Dufault B. Differences in the gingival crevicular fluid composition between adults and adolescents undergoing orthodontic treatment. Angle Orthod. 2014;84(1):120-6.

[16] ¹⁶
Bolamperti L, Montanari P, Levrini L, Macchi A, Tagliabue A, Caprioglio A. Tissue response during self-ligating treatment. Prog Orthod. 2012;13(2):109-16.

[17] ¹⁷
Canavarro C, Teles RP, Capelli Júnior J. Matrix metalloproteinases -1, -2, -3, -7, -8, -12, and -13 in gingival crevicular fluid during orthodontic tooth movement: a longitudinal randomized split-mouth study. Eur J Orthod .2013;35(5):652-8.

[18] ¹⁸
Grant M, Wilson J, Rock P, Chapple I. Induction of cytokines, MMP9, TIMPs, RANKL and OPG during orthodontic tooth movement. Eur J Orthod. 2013;35(5):644-51.

[19] ¹⁹
Alfaqeeh SA, Anil S. Lactate dehydrogenase activity in gingival crevicular fluid as a marker in orthodontic tooth movement. Open Dent J. 2011;5:105-9.

[20] ²⁰
Capelli J Jr, Kantarci A, Haffajee A, Teles RP, Fidel R Jr, Figueredo CM. Matrix metalloproteinases and chemokines in the gingival crevicular fluid during orthodontic tooth movement. Eur J Orthod. 2011;33(6):705-11.

[21] ²¹
Rhee SH, Kang J, Nahm DS. Cystatins and cathepsin B during orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2009;135(1):99-105.

[22] ²²
Cantarella G, Cantarella R, Caltabiano M, Risuglia N, Bernardini R, Leonardi R. Levels of matrix metalloproteinases 1 and 2 in human gingival crevicular fluid during initial tooth movement. Am J Orthod Dentofacial Orthop. 2006;130(5):568.e11-6.

[23] ²³
Hoshino-Itoh J, Kurokawa A, Yamaguchi M, Kasai K. Levels of t-PA and PAI-2 in gingival crevicular fluid during orthodontic tooth movement in adults. Aust Orthod J. 2005;21(1):31-7.

[24] ²⁴
Batra P, Kharbanda OP, Duggal R, Singh N, Parkash H. Alkaline phosphatase activity in gingival crevicular fluid during canine retraction. Orthod Craniofac Res. 2006;9(1):44-51.

[25] ²⁵
Isik F, Sayinsu K, Arun T, Unlüçerçi Y. Bone marker levels in gingival crevicular fluid during orthodontic intrusive tooth movement: a preliminary study. J Contemp Dent Pract. 2015;6(2):27-35.

[26] ²⁶
Perinetti G, Serra E, Paolantonio M, Bruè C, Meo SD, Filippi MR, et al. Lactate dehydrogenase activity in human gingival crevicular fluid during orthodontic treatment: a controlled, short-term longitudinal study. J Periodontol. 2005;76(3):411-7.

[27] ²⁷
Ingman T, Apajalahti S, Mäntylä P, Savolainen P, Sorsa T. Matrix metalloproteinase-1 and -8 in gingival crevicular fluid during orthodontic tooth movement: a pilot study during 1 month of follow-up after fixed appliance activation. Eur J Orthod. 2005;27(2):202-7.

[28] ²⁸
Perinetti G, Paolantonio M, Serra E, D'Archivio D, D'Ercole S, Festa F, et al. Longitudinal monitoring of subgingival colonization by Actinobacillus actinomycetemcomitans, and crevicular alkaline phosphatase and aspartate aminotransferase activities around orthodontically treated teeth. J Clin Periodontol 2004;31(1):60-7.

[29] ²⁹
Sugiyama Y, Yamaguchi M, Kanekawa M, Yoshii M, Nozoe T, Nogimura A, Kasai K. The level of cathepsin B in gingival crevicular fluid during human orthodontic tooth movement. Eur J Orthod. 2003;25(1):71-6.

[30] ³⁰
Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Tripodi D, Femminella B, et al. Alkaline phosphatase activity in gingival crevicular fluid during human orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2002;122(5):548-56.

[31] ³¹
Tzannetou S, Efstratiadis S, Nicolay O, Grbic J, Lamster I. Interleukin-1 beta and beta-glucuronidase in gingival crevicular fluid from molars during rapid palatal expansion. Am J Orthod Dentofacial Orthop. 1999;115(6):686-96.

[32] ³²
Uematsu S, Mogi M, Deguchi T. Interleukin (IL)-1 beta, IL-6, tumor necrosis factor-alpha, epidermal growth factor, and beta 2-microglobulin levels are elevated in gingival crevicular fluid during human orthodontic tooth movement. J Dent Res. 1996;75(1):562-7.

[33] ³³
Karaduman B, Uraz A, Altan GN, Tuncer BB, Alkan O, Gönen S, et al. Changes of tumor necrosis factor-?, interleukin-10, and tartrate-resistant acid phosphatase 5b in the crevicular fluid in relation to orthodontic movement. Eur J Inflamm. 2015;13(1):3-13.

[34] ³⁴
Wahab RMA, Yamamoto R, Sintian A, Kasim NA, Abidin IZZ, Senafi S, et al. The effects of orthodontic forces during canine retraction using self- ligating brackets on gingival crevicular fluid enzyme activity, canine movement and root resorption. Sains Malaysiana. 2015;44(2):249-56.

[35] ³⁵
Ariffin SHZ, Kasim NA, Wahab RMA, Jemain AA. Lactate dehydrogenase activity during tooth movement under 1.0 N and 1.5 N continuous force applications. Sains Malaysiana. 2013;42(1):99-105.

[36] ³⁶
Wahab RMA, Dasor MM, Senafi S, Abdullah AAA, Jemain AA, Kasim NA, et al. Crevicular tartrate resistant acid phosphatase activity and rate of tooth movement under different continuous force applications. African J Pharmacy Pharmacol. 2011;5(20):2213-9.

[37] ³⁷
Abdullah AAA, Wahab RMA, Ariffin SHBZ. Pattern of crevicular alkaline phosphatase during orthodontic tooth movement: leveling and alignment stage. Sains Malaysiana. 2011;40(10):1147-51.

[38] ³⁸
Asma AAA, Rohaya MAW, Hisham ZAS. Crevicular alkaline phosphatase activity during orthodontic tooth movement: canine retraction stage. J Med Sci. 2008;8(3):228-33.

[39] ³⁹
Rohaya MAW, Hisham ZAS, Khazlina K. The activity of aspartate aminotransferase during canine retraction (bodily tooth movement) in orthodontic treatment. J Med Sci. 2008;8:553-8.

[40] ⁴⁰
Rohaya MAW, Hisham ZAS, Khazlina K. Preliminary study of aspartate aminotransferase activity in gingival crevicular fluids during orthodontic tooth movement. J Applied Sci. 2009;9(7):1393-96.

[41] ⁴¹
Hassan KS, Alagl SA, Ali I. Periodontal status following self-ligature versus archwire ligation techniques in orthodontically treated patients: Clinical, microbiological and biochemical evaluation. Orthod Waves. 2010;69:164-70.

[42] ⁴²
Farahani M, Safavi MS, Dianat O, Tusi SK, Younessian F. Acid and alkaline phosphatase levels in gcf during orthodontic tooth movement. J Dent Shiraz Univ Med Sci. 2015;16(3 Suppl): 237-45.

[43] ⁴³
Jeyraj Y, Katta AK, Vannala V, Lokanathan D, Reddy SN, Rajasigamani K. Estimation of alkaline phosphatase in the gingival crevicular fluid during orthodontic tooth movement in premolar extraction cases to predict therapeutic progression. J Nat SciBiolMed. 2015;6(2):343-6.

[44] ⁴⁴
Perinetti G, D'Apuzzo F, Contardo L, Primozic J, Rupel K, Perillo L. Gingival crevicular fluid alkaline phosphate activity during the retention phase of maxillary expansion in prepubertal subjects: A split-mouth longitudinal study. Am J Orthod Dentofacial Orthop. 2015 July;148(1):90-6.

[45] ⁴⁵
Arifyezdani A. Alkaline phosphatase activity in gingival crevicular fluid: a diagnostic marker to assess human orthodontic tooth movement. Biomed Pharmacol J. 2015;8(Spl. Edn): 293-301.

[46] ⁴⁶
Arifyezdani A. Acid phosphatase activity in gingival crevicular fluid during human orthodontic tooth movement. Biomed Pharmacol J. 2015; 8(Spl. Edn):403-8.

[47] ⁴⁷
Lakshmanan P, Sathya PB, Dilip S, Srinivas S. Evaluation of lactate dehydrogenase levels in gingival crevicular fluid during orthodontic tooth movement an in-vivo study. Res J Pharmaceutical Biol Chem Sci. 2015;6(5):877-88.

[48] ⁴⁸
Perinetti G, Paolantonio M, D'Attilio M, D'Archivio D, Dolci M, Femminella B, et al. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic treatment. A controlled short-term longitudinal study. J Periodontol. 2003;74(2):145-52.

[49] ⁴⁹
Kalha AS, Kachiwala VA, Govardhan SN, McLaughlin RP, Khurshaid SZ. Redefining orthodontic space closure: sequential repetitive loading of the periodontal ligament-a clinical study. World J Orthod. 2010;11(3):221-9.

[50] ⁵⁰
Saloom HF, Papageorgiou SN, Carpenter GH, Cobourne MT. Impact of obesity on orthodontic tooth movement in adolescents: a prospective clinical cohort study. J Dent Res. 2017;96(5):547-54.

[51] ⁵¹
Delli Mauri A, Petrini M, Vitale D, Tecco S, Festa F, Barbato E, et al. Alkaline phosphatase level in gingival crevicular fluid during treatment with Quad-Helix. J Biol Regul Homeost Agents. 2015 Oct-Dec;29(4):1017-23.

[52] ⁵²
Fatima A, Talapaneni AK, Saleh A, Sana S, Hussain A. An evaluation and comparison of myeloperoxidase enzymatic activity during initial orthodontic alignment: an in vivo study. J Orthod. 2017 Sept;44(3):169-173.

[53] ⁵³
Bhasin V, Singh M, Goutam M, Singh S, Nigam AS, Joshi A. Comparative evaluation of myeloperoxidase enzymatic activity in gingival crevicular fluid of subjects having orthodontic treatment by different aligning arch wires. J Contemp Dent Pract. 2017;18(10):977-80.

[54] ⁵⁴
Haq AU, Iqbal J, Hussain K, Munir A, Irfan S. Aspartate aminotransferase activity in gingival crevicular fluid during orthodontic tooth movement. APMC. 2017;11(2):149-53.

[55] ⁵⁵
Lamster IB, Hartley LJ, Vogel RI. Development of a biochemical profile for gingival crevicular fluid. Methodological considerations and evaluation of collagen-degrading and ground substance degrading enzyme activity during experimental gingivitis. J Periodontol. 1985 Nov;56 Suppl 11S:13-21.

[56] ⁵⁶
Burstone CJ. The biomechanics of tooth movement. In: Kraus BS, Riedel RA, editors. Vistas in Orthodontics. Philadelphia: Lea & Febiger; 1962. p. 197-213.

[57] ⁵⁷
Pilon JJ, Kuijpers-Jagtman AM, Maltha JC. Magnitude of orthodontic forces and rate of bodily tooth movement: an experimental study in beagle dogs. Am J Orthod Dentofacial Orthop. 1996 Jul;110(1):16-23.

[58] ⁵⁸
van Leeuwen EJ, Maltha JC, Kuijpers-Jagtman AM. Tooth movement with light continuous and discontinuous forces in beagle dogs. Eur J Oral Sci. 1999 Dec;107(6):468-74.

[59] ⁵⁹
Apajalahti S, Sorsa T, Railavo S, Ingman T. The in vivo levels of matrix metalloproteinase-1 and -8 in gingival crevicular fluid during initial orthodontic tooth movement. J Dent Res. 2003;82:1018-22.

[60] ⁶⁰
Redlich M, Reichenberg E, Harari D, Zaks B, Shoshan S, Palmon A. The effect of mechanical force on mRNA levels of collagenase, collagen type I, and tissue inhibitors of metalloproteinases in gingivae of dogs. J Dent Res. 2001 Dec;80(12):2080-4.

[61] ⁶¹
Welgus HG, Jeffrey JJ, Eisen AZ. The collagen substrate specificity of human skin fibroblast collagenase. J Biol Chem. 1981 Sept 25;256(18):9511-5.

[62] ⁶²
Beklen A, Tüter G, Sorsa T, Hanemaaijer R, Virtanen I, Tervahartiala T, et al. Gingival tissue and crevicular fluid co-operation in adult periodontitis. J Dent Res. 2006 Jan;85(1):59-63.

[63] ⁶³
Nahm DS, Kim HJ, Mah J, Baek SH. In vitro expression of matrix metalloproteinase-1, tissue inhibitor of metalloproteinase- 1 and transforming growth factor-beta1 in human periodontal ligament fibroblasts. Eur J Orthod. 2004 Apr;26(2):129-35.

[64] ⁶⁴
Bolcato-Bellemin AL, Elkaim R, Abehsera A, Fausser JL, Haikel Y, Tenenbaum H. Expression of mRNAs encoding for alpha and beta integrin subunits, MMPs, and TIMPs in stretched human periodontal ligament and gingival fibroblasts. J Dent Res. 2000 Sep;79(9):1712-6.

[65] ⁶⁵
He Y, Macarak EJ, Korostoff JM, Howard PS. Compression and tension: differential effects on matrix accumulation by periodontal ligament fibroblasts in vitro. Connect Tissue Res. 2004;45(1):28-39.

[66] ⁶⁶
Takahashi I, Onodera K, Nishimura M, Mitnai H, Sasano Y, Mitani H. Expression of genes for gelatinases and tissue inhibitors of metalloproteinases in periodontal tissues during orthodontic tooth movement. J Mol Histol. 2006 Nov;37(8-9):333-42.

[67] ⁶⁷
Bildt MM, Bloemen M, Kuijpers-Jagtman AM, Von den Hoff JW. Matrix metalloproteinases and tissue inhibitors of metalloproteinases in gingival crevicular fluid during orthodontic tooth movement. Eur J Orthod. 2009 Oct;31(5):529-35.

[68] ⁶⁸
Clark IM, Powell LK, Cawston TE. Tissue inhibitor of metalloproteinases (TIMP-1) stimulates the secretion of collagenase from human skin fibroblasts. Biochem Biophys Res Commun. 1994 Sept 15;203(2):874-80.

[69] ⁶⁹
Garlet TP, Coelho U, Silva JS, Garlet GP. Cytokine expression pattern in compression and tension sides of the periodontal ligament during orthodontic tooth movement in humans . Eur J Oral Sci. 2007 Oct;115(5):355-62.

[70] ⁷⁰
Keeling SD, King GJ, McCoy EA, Valdez M. Serum and alveolar bone phosphatase changes reflect remodeling during orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 1993 Apr;103(4):320-6.

[71] ⁷¹
Whyte MP. Hypophosphatasia and the role of alkaline phosphatase in skeletal mineralization. Endocr Rev. 1994 Aug;15(4):439-61.

[72] ⁷²
Savic L, Savic D. Serum calcium and phosphorus concentration and alkaline phosphatase activity in healthy children during growth and development. Med Pregl. 2008 July-Aug;61(7-8):393-9.

[73] ⁷³
Christenson RH. Biochemical markers of bone metabolism: an overview. Clin Biochem. 1997;30:573-93.

[74] ⁷⁴
Rody WJ Jr, King GJ, Gu G. Osteoclasts recruitment to sites of compression in orthodontic tooth movement. Am J Orthod Dentofacial Orthop. 2001 Nov;120(5):477-89.

[75] ⁷⁵
Casa MA, Faltin RM, Faltin K, Arana-Chavez VE. Root resorption on torqued human premolars shown by tartrate resistant acid phosphatase histochemistry and transmission electron microscopy. Angle Orthod. 2006 Nov;76(6):1015-21.

[76] ⁷⁶
Williams DL, Marks V. Biochemistry in clinical practice. London: William Heinemann Medical Books;1983.

[77] ⁷⁷
McCulloch CA. Host enzymes in gingival crevicular fluid as diagnostic indicators of periodontitis (Review). J Clin Periodontol. 1994 Aug;21(7):497-506.

[78] ⁷⁸
Yost KG, Mallatt ME, Liebman J. Interproximal gingivitis and plaque reduction by four interdental products. J Clin Dent. 2006;17(3):79-83.

[79] ⁷⁹
Serra E, Perinetti G, D'Attilio M, Cordella C, Paolantonio M, Festa F, et al. Lactate dehydrogenase activity in gingival crevicular fluid during orthodontic treatment. Am J Orthod Dentofacial Orthop. 2003 Aug;124(2):206-11.

[80] ⁸⁰
Monga N, Chaurasia S, Kharbanda OP, Duggal R, Rajeswari MR. A study of interleukin 1? levels in peri-mini screw crevicular fluid (PMCF). Prog Orthod. 2014;15(1):30-35.

Criteria	Sub criteria	Inclusion	Exclusion
Participants/population	Type of sample	Human studies	Animal studies, in vitro studies
	Age groups	if specified	Not mentioned
	Male to female ratio	if specified	Not mentioned
	Controls	present (either internal /external)	No controls
	Sample size (sample size, not number of teeth studied)	≥5	<5
Intervention(s), exposure(s)	Mediators studied	enzymes [AST, MPO, ALP,βG, LDH, CatB, Cs, cAMP RII, MMPs]	Other than enzymes (cytokines/ hormones/PGs)
	Exposure	Orthodontic force application in healthy patients	Studied in periodontal inflammation/ root resorption/ not related
	Orthodontic mechanics	Specified	Not specified
	Oral hygiene regimen	Mentioned	Not mentioned
	Use of antibiotic/anti-inflammatory drugs	Not used	Not mentioned/ used
	Medium of study	GCF	Other than GCF/ peri-implant fluid/saliva
	GCF sample collection instrument	Periopaper/micropipette/ endodontic paper	Not mentioned

S. No.	Criteria (29)		Response
	Yes	No	Unclear
I. Study design
1.	Objective: objective clearly formulated
2.	Sample size: considered adequate
3.	Spectrum of patients representative of patients receiving the test in practice
4.	Ethical clearance mentioned
5.	Selection criteria: clearly described
6.	Randomization: stated
7.	Baseline characteristics: clearly defined
8.	Control: clearly defined
9.	Orthodontic mechanics explained in sufficient detail to permit replication of experiment
10.	Orthodontic force: clearly specified
11.	Description of execution of index test: sufficient to permit replication of test
12	Absence of time difference between index test & control: mentioned
13.	Index test executed at specified time and environmental conditions
14.	Use of proper indices for assessment of gingival & periodontal status (pre-treatment)
15.	Use of proper indices for assessment of gingival & periodontal status (at each observation time)
16.	Oral hygiene regime: mentioned
17.	Prophylaxis done (pre-treatment)
18.	Prophylaxis done (at each observation time)
II. Study measurements
1.	GCF handling characteristics: explained
2.	Measurement method: appropriate to the objective
3.	Reliability: adequate level of agreement
III. Statistical analysis
1.	Dropouts: dropouts included in data analysis
2.	Statistical analysis: appropriate for data
3.	Confounders: confounders included in analysis
4.	Statistical significance level: P value stated
5.	Confidence intervals provided
IV. Study results and conclusions (3)
1.	Index test compared to baseline
2.	Index test compared to control
3.	Conclusions: specific

Ref No.	Oral px (Pre t/t)	Oral px (Every ob po)	Oral hy instr/motiv	Mw	fq/o mw/d	asm for gv & pd in (pre t/t )	At every ob po
7	Y	NM	Y	Cx glu	2	Y	Y
8	Y	NM	NM	NM	NM	Y	NM
9	NM	NM	Y	0.15% Benz HCL/d	1 /d	NM	NM
10	Y	NM	Y	0.5 oz of 0.2% cx glu	2/d	NM	NM
11	Y	NM	NM	NM	NM	Y	NM
12	NM	NM	NM	NM	NM	NM	NM
13	Y	Y	Y	NM	NM	NM	NM
14	Y	NM	Y	NM	NM	Y	Y
15	Y	NM	NM	NM	NM	Y	NM
16	Y	Y	Y	NM	NM	Y	Y
17	Y	Y	Y	0.5 oz of 0.2% cx glu	2/d	Y	Y
18	NM	NM	NM	NM	NM	Y	Y
19	Y	Y	Y	0.5 oz of 0.2% cx glu	Y	Y	Y
20	Y	Y	Y	0.12% cx glu	2 /d for 4 wk	NM	NM
21	NM	NM	Y	NM	NM	Y	NM
22	NM	NM	Y	NM	NM	NM	NM
23	Y	Y	NM	NM	NM	Y	Y
24	Y	Y	Y	cx glu	2/d	Y	NM
25	NM	NM	NM	Benz HCL	NM	NM	NM
26	Y	NM	Y	NM	NM	Y	Y
27	NM	NM	NM	NM	NM	Y	NM
28	Y	NM	Y	NM	NM	Y	Y
29	NM	NM	NM	NM	NM	Y	NM
30	NM	NM	Y	NM	NM	Y	Y
31	Y	NM	Y	cx glu	NM	Y	Y
32	NM	NM	NM	NM	NM	Y	Y
33	Y	NM	Y	NM	NM	Y	Y
34	NM	NM	Y	NM	NM	NM	NM
35	Y	NM	Y	NM	NM	NM	NM
36	Y	NM	NM	NM	NM	NM	NM
37	Y	Y	Y	N	N	Y	Y
38	Y	Y	Y	N	N	Y	Y
39	Y	Y	Y	N	N	Y	Y
40	Y	Y	Y	N	N	Y	T
41	Y	Y	Y	N	N	Y	Y
42	NM	NM	Y	cx glu	2 /d	Y	Y
43	Y	NM	Y	N(against it)	N	Y	NM
44	Y	Y	Y	0.012% cx glu	2/d	Y	Y
45	Y	Y	Y	Cx glu	NM	Y	Y
46	Y	Y	Y	NM	NM	Y	Y
47	Y	NM	Y	NM	NM	Y	NM
48	Y	NM	Y	NM	NM	Y	Y
49	NM	NM	NM	NM	NM	NM	NM
50	NM	NM	NM	NM	NM	Y	Y
51	Y	Y	NM	NM	NM	Y	NM
52	Y	NM	Y	NM	NM	Y	NM
53	Y	NM	Y	NM	NM	Y	NM
54	Y	NM	NM	NM	NM	Y	NM

Ref No.	sts al ap	cf	Drop outs	Up / down rg	Pk	sd oc	cr	sts sn rd
7	1-tailed paired Student t	Y	NM	βG: inc	M-010 PM-07 CI-08	IL-1β sign inc for Mo- O5 to O10 for PM-O6 to 010 For CI-04, 06, 07, 09, 010 & dec at O2 for Mo, PM, CI	stronger F cause higher levels of IL-1β & βG	βG inc for Mo- 07 to 010 PM-07, 08, 010 CI-06, 07, 010 & dec at O2 for Mo, PM, CI
8	ANOVA, paired t test	Y	NaM	Inc at 2h, bas in 7d	2h	Inc MPO in saliva at 2h, B in 7d	+ve cr of lvl in GCF & saliva	Inc at 2h
9	(ANOVA) Kolmogorov-Smirnov test, Paired-samples test	Y	N	Inc	2wk	NM	NM	In cns F: Lvl pk at 2wk In gradually inc F: Lvl pk at 3wk
10	Kolmogorov and Smirnov (ANOVA) & Tukey’s post-hoc test	Y	N	Inc	14d	GCF vol inc from 0 - 21d Sn inc at 14d	Exp si; lvl inc on 14d cr with pk in GCF vol	Exp si; pk at 14d
11	Paired t test Pearson’s cr	Y	N	LDH inc at 2, 3& 4 wk(100 g) & 1, 2 & 3wk (150 g). AST inc at 4 & 5wk (100 g) & 3 & 4wk (150 g). TRAP inc at 5wk (100 g)	AST: 1wk TRAP: 2wk ALP: 5wk	In saliva:AST inc at 5wk, TRAP at 2wk, ALP at 1 to 5wk	Weak cr b/w enz quantity & activity	LDH inc at 2, 3 & 4 wk (100 g) & 1, 2 & 3wk (150 g). AST inc at 4 & 5wk (100 g) & 3 & 4wk (150 g) TRAP inc at 5wk (100 g)
12	Friedman test for intergp & intragp, Wilcoxon test for related samples, Kruskal-Wallis test for independent samples in both gps	Y	N	inc	2h	minm & severe crw: inc from 0 at 2h, 7d, 14d in saliva	No cr of crw with change in MPO	At 2h, 7d sn inc from B & 14d
13	Intra gp: Friedman’s test, Wilcoxon test Inter gp: Mann-Whitney U test, Pearson’s test	Y	N	inc	MMP9: 8h MMP9/NGAL: 72h	TSP1: inc from B at 8h to 72h, dec at 1wk	Strong & sn cr b/w MMP9/NGAL & TSP1 in IxT	MMP9: inc from B at 4h, 8h, 1wk, 2wk. MMP9/NGAL: inc from B at 8h,24h, 72h
14	Intergp: Mann Whitney U test. Intra gp: Students unpaired t-test	Y	N	Inc	ACP: 3d ALP, AST: 15d	NM	NM	Inter gp; ACP: pk at 3d ALP, AST: pk at 15d Intra gp: ACP, ALP, AST higher in Mx I than Mo
15	SAS version 9.2 proc mixed subroutine	Y	N	No sts sn change	NM	Exp si: in Ad, IL-1/1L-1RA dec in 3wk aftr 1st wi lig ado, RANKL/OPG pk at 6wk aftr 1st rect wi lig	NM	b/w Exp & cT; no sts sn change B/w Ad & adol: no sts sn diff
16	MedCalc software Intergp: Student’s t-test, ANOVA.	Y	N	SL+ NiTi wi: inc SL+ thrm wi: dec	No sts sn change	Visual pl scr dec sts sn	NM	No sts sn change b/w Exp & cT or within each gp
17	Luminex analysis	Y	N	MMP1,3:inc, pk at 24h MMP8: pk at 14d	24h	NM	NM	No sts sg diff b/w comp & tn, MMP1, 3: inc, pk at 24h MMP8: pk at 14d
18	Paired non-parametric Kruskall-Wallis. Spearman Rank Sum anal	Y	NM	Inc	Exp-TIMP, MMP-9:4h cmp: TIMP-1, MMP-9:4h, TIMP-2: 7d	+ve cr of GCF vol & PI at 0 at tn, cmp +ve cr of TNF-α, IL-1β, IL-8, GM-CSF to speed of OTM at 4h in Exp cr of IL-1β, IL-8, TNF-α inc to if at 0 at cmp	+ve cr of MMP-9 & TIMP to speed of OTM at 4h in Exp	TIMP1 & 2, MMP-9 inc at 4h in Exp
19	GraphPad®Instat, ANOVA, Friedman	Y	NM	Inc	14d, 21d	NM	NM	Inc at 7, 14, 21d
20	Friedman, Mann-Whitney	Y	NM	Inc	1h	GCF vol higher in cmp than tn at 21d	NM	MMPs inc at 1h, dec at 24h
21	ANOVA		NM	Cp: dec Cys:inc	1d	GCF vol inc in 1d, dec at 1m	-ve cr in Cp & Cys Lvl	Cp;dec at 1d, inc to B in 1m Cys;inc in 1d, dec to B in 1
22	ANOVA	Y	NM	Inc	MMP1-1h MMP2-1h,8h	NM	NM	Inc in MMP1 (tn) -1h-3h, (cmp) -1h Inc in MMP2 (tn) - 1h, (comp)-8h
23	Mann-Whitney U-tests	N	NM	Inc at 24h at Ix t >cT	24h	GCF vol no sn diff at 24h	NM	Inc at 24h
24	ANOVA &LSD	Y	NM	Inc	14d	NM	NM	Inc in ALP -7, 14 at Ms & D
25	Friedman test	Y	NM	Dec	I d	Dpd, osteocalcin dec	NM	Dec from 0 to 28 d, inc on 7d
26	Friedman and Bonferroni-corrected, Wilcoxon paired signed rank tests	Y	NM	Inc	14d	NM	NM	ct gp greater than Ag gp on 14 d & 21d
27	NM	Y	NM	Lvl of MMP-8 inc in Ix t>c	NM	NM	NM	Lvl of MMP-8 inc 12 times in Ix t>c
28	Friedman & Bonferroni-corrected, Wilcoxon paired signed rank tests	Y	NM	Inc	28d	Aa colonization inc sn on 28d in ExpT & ct gp	NM	Inc at 28d in Ix T as compd to Ct T & Ag T
29	Friedman & Bonferroni-corrected, Wilcoxon paired signed rank tests	Y	NM	Inc	tn:7d cmp:7&14d	NM	NM	AST: inc in Ix T & ct T as compd to Ag T, inc in IxT as compd to ctT on tn si on 14d & on cmp on 7d & 14d, inc in IxT on cmp than tn on 7d
30	Mann Whitney U-test	Y	N	Inc	24h		NM	CpB higher at 24h at IxT
31	Bonferroni-corrected, 1-way repeated measures ANOVA, paired Student t test	Y	NM	Inc	14d	NM	NM	Sign inc on both M & D at 1,2,3,4 wks
32	One-tailed paired Student t test	Y	N	Inc	βG -25d IL-1β-	sn inc in IL-1β level at 4d &19d to 60d AL	NM	inc in βG at 25d to 60d AL
33	Student’s t test	Y	N	IL-1β, IL-6, TNF-α, EGF, β2-µG	inc	24h	Intra-grp in Exp: IL-1β inc at 24h > BS,IL-6 inc at 24h > BS or 168h,TNF-α inc at 24h > BS or 168h, EGF inc at 24h>BS Intergrp btw cont & Exp: IL-1β inc in Exp>cont at 24h, Mean IL-6 in Exp >ant cont, TNF-αin Exp at 24h> ant cont, EGF in Exp at 24hr> ant cont	NM
Ref No.	sts al ap	cf	Drop outs	Up / down rg	Pk	sd oc	cr	sts sn rd
34	ANOVA	Y	NM	Inc	7d	TNF-α in D & Ms sites of TT sn higher than both sites of c, also >.B, inc sn at 1 h & 24h. IL-10 dec during Exp period at c & TT	NM	TRAP5b Level in D & Ms sites of TT were sn higher than that at both sites of cT compd with B values, inc was sn at 1 h & 24h.
35	Shapiro-Wilk test	Y	NM	inc	100g gp-TRAP-3wk 150g gp-ALP & TRAP -5wk	NM	NM	In 100 g gp, TRAP sn inc in 3-5 wk compd to TRAPB. ALP & AST slightly inc. In 150 g gp, ALP & TRAP slightly inc compd with their B. AST sn inc in 5 wk.
36	Student’s paired t test	Y	NM	Inc	M:4wk D:1.5N-2wk	NM	NM	LDH at Ms site in 1.0 N &1.5 N gp, inc sn on 4th wk. At D site, LDH with 1.5 N was higher than 1.0 N throughout 5 wk of TM. LDH with 1.5 NF inc at both Ms (wk 2) & D site (wk 3) with sn diff to 1.0 N F
37	Kruskal Walis test.	Y	NM	TRAP inc in 150g F: Ms site peak 3wk, D site Pk 4wk den dec 100g F: Ms site 2wk Pk den dec, D site 5wk 4wk: Lvl in 150g> 100g F (D site) 5wk: Lvl in 100g>150g F (Dsite)	150g: D site -4wk, Ms site-3wk 100g:D site-5wk. Ms site-2wk	Rate of OTM at 150g>100g	150g F at 3 & 4wk>100g f, +ve cr of Lvl of TRAP & rate of OTM	150g gp, Ms si: inc at 3wk>BS At D si: inc at 4k>BS TRAP at 150 gm>100gm F at 4wk (D site)
38	Paired sample t-test	Y	NM	inc, pk at 2wk, at D >Ms- 1wk	Ms, D Si: 2wk	NM	NM	Inc at 1wk, 2wk from Bas
39	Paired sample t-test	Y	NM	Dec: 1wk,4wk on Ms, D si	4wk	NM	-ve cr of amt of OTM & Lvl of ALP	Dec at 4wk
40	Wilcoxon signed rank test	Y	NM	Inc: at 1wk,4wk, stabilised	4wk	NM	NM	Inc at 1wk, 4wk, At D si>Ms si
41	Wilcoxon signed rank test	Y	NM	Inc at 1wk, dec in next 3wk	1wk	N	NM	Pk at 1wk at Ix T>cT
42	unpaired and paired t-test	Y	NM	Inc at archwi >self lig site, inc at 1wk	1wk	Bac count in archwi>self lig	+ve cr in self lig & AST Lvl	Inc at archwi >self lig
43	ANOVA, paired t-test using SPSS	Y	NM	ALP, ACP inc at 14d, 28d, ALP at Ms>D, ACP inc in Ms &D	ALP, ACP : 14d	NM	NM	ALP, ACP inc, ALP inc more on M si
44	ANOVA, Student's t-test	Y	NM	ALP dec, D of C > Ms of 2nd PM on 1, 7, 14, 21, 28d	Dec	NM	NM	Dec at D of C > Ms of 2nd PM on 1, 7, 14, 21, 28d
45	Friedman test followed by a Bonferroni-corrected Wilcoxon paired signed rank test	Y	Y	ALP inc in 3m, 6m	Inc	PD with ALP actv	+ve corr of ALP lvl with time at tn si	ALP at 3m, 6m > cT
46	ANOVA,Tukey’s HSD Post-Hoc test, Mann-Whitney U-test	Y	NM	ALP inc 14d, 28d	28d	NM	NM	ALP at Ms si of TT>CT at 14d, 28d At Ms si>Dsi at 14d, 28d
47	ANOVA, Independent Samples t-test, Mann- Whitney U-test	Y	NM	ACP inc both Ms & D si D si>M si at 7d, 21d	21d	NM	NM	D si>M si at 7d, 21d TT>cT at 7d, 21 d at Dsi
48	ANOVA,Tukey HSD	Y	NM	LDH inc at TT>cT 7d, 14d,21d	28d	NM	NM	LDH inc frm 7d-14d at TT, TT>cT at 7, 14, 21d
49	Friedman & Bonferroni-corrected Wilcoxon paired signed rank tests	Y	N	AST inc from BS in T/t gp from BS to 2wk followed by dec Inc in CC gp from BS to 1wk followed by dec AST level in comp >tn on 1wk	14d	GCF flow in T/t=CC>AC gp	+ve correl of mechanical stress to AST levels, T/t>CC	sn inc in T/t &CC vs AC gp: 1, 2, 3, 4w sn inc in T/t vs CC gp: 1, 2wk AST level in comp >tn on 1wk
50	One-way ANOVA was used for multiple group and Student t test for group-wise comparisons	Y	N	inc in ALP b/w 21d & 28d :of 200% in active TB gp, of 260% in Rt screw gp	TB: 21d Rt screw:28d	Space closure rate, root resorption, Rt, anchorage loss with Hycon screw were assessed	+ve correl of ALP in Hycon screw gp with actvn of screw	Sign diff in ALP on 21d & 28d b/w TB & Rt screw gp
51	independent t tests, _2 tests, or Mann-Whitney, intraexaminer reliability - concordance correlation coefficient (CCC) & Bland-Altman method	N	Y	MMP8,9, MMP8/TIMP1, MMP9/TIMP1, resistin at BS>1h>1wk>compl of Aln CRP, MPO, TIMP, RANKL inc from BS to compl of Aln Adiponectin BS<1h<1wk>compl of Aln Leptin dec from BS to compl of Aln	NM	resistin at BS>1h>1wk>compl of Aln CRP, RANKL inc from BS to compl of Aln Adiponectin BS<1h<1wk>compl of Aln Leptin dec from BS to compl of Aln	Mediators correl with Aln rate- MPO, RANKL, Leptin, Resistin	MPO at BS<1h<1d<compl of Aln
52	Fisher’s PLSD followed by post hoc, Bonferroni- Dunn	Y	N	ALP on cmp site: 0>2wk>4wk<1y tn site: 0<2wk<4wk<1y	tn site: 1y cmp site: before actvn	NM	+ve correl of intermolar distance with ALP level in tn site	tn site:0 (before actvn) < 4wk, 0<1y cmp site: 0>4wk, 0<1y, 2wk>4wk
53	paired & unpaired ‘t’ test and ANOVA.	Y	N	MPO inc from BS to 2h in HANT, SE, MSSS gp	2h	NM	MPO in HANT>SE>MSSS	sn diff in MPO b/w SE & MSSS :2h, 2wk, b/w HANT & MSSS:2h, b/w SE & MSSS:1wk
54	Chi-square Student’s t-test, and one-way analysis of variance	Y	N	MPO inc from BS to 2h in HANT, SE, MSNiTi gp, HANT>SE & MS NiTi:2h	2h	NM	NM	sn diff b/w SE & MSNiTi: 2h, 1, 2wk, b/w HANT & MSNiTi:2h
55	Independent & paired sample t- test	Y	N	AST inc from BS to 1wk, then dec in Exp gp	1wk	NM	NM	Levels greater in Exp than Cn gp at 1, 2, 3, 4wk

Brasil

Brasil

Effect of orthodontic forces on levels of enzymes in gingival crevicular fluid (GCF): A systematic review

Abstract

Objective:

Methods:

Results:

Conclusions:

Resumo

Objetivo:

Métodos:

Resultados:

Conclusões:

INTRODUCTION

MATERIAL AND METHODS

Protocol and registration

Evaluation of risk of bias / quality of individual studies

RESULTS

Oral hygiene regimen and gingival health assessment (Table 4)

GCF characteristics (Table 5)

DISCUSSION

CONCLUSIONS

REFERENCES

Publication Dates

History