Nilson Antonio Nunes Junior 
 
 
 
 
 
 
 
 
 

EFEITO DE UM NOVO AGENTE CLAREADOR PARA USO 

PROFISSIONAL CONTENDO HEXAMETAFOSFATO E FLUORETO 

SOBRE A EFICÁCIA CLAREADORA, DIFUSÃO TRANS- 

AMELODENTINÁRIA E MICRODUREZA: ESTUDO IN VITRO 

 
 
 
 
 
 
 
 
 
 
 
 
 

 
Araçatuba – SP 

2022 



 

Nilson Antonio Nunes Junior 
 
 
 
 

EFEITO DE UM NOVO AGENTE CLAREADOR PARA USO PROFISSIONAL 

CONTENDO HEXAMETAFOSFATO E FLUORETO SOBRE A EFICÁCIA 

CLAREADORA, DIFUSÃO TRANS-AMELODENTINÁRIA E MICRODUREZA: 

ESTUDO IN VITRO 

 
 
 
 

Dissertação apresentada à Faculdade de Odontologia 

da Universidade Estadual Paulista “Júlio de Mesquita 

Filho”, Campus de Araçatuba, para obtenção de título de 

Mestre em Ciência Odontológica - Área de 

Concentração: Biomateriais. 

 
 

 
Orientador: Profº. Titular. Alberto Carlos Botazzo Delbem 

 
 
 
 
 
 
 
 
 
 
 
 
 

Araçatuba – SP 
2022 



 
 
 
 
 
 
 
 
 
 
 
 

 

Catalogação-na-Publicação 

Diretoria Técnica de Biblioteca e Documentação – FOA / UNESP 
 

Ana Claudia M. Grieger Manzatti CRB-8/6315 

 

Nunes Junior, Nilson Antonio. 
N972e  Efeito de um novo agente clareador para uso 

profissional contendo hexametafosfato e fluoreto sobre a 
eficácia clareadora, difusão trans-amelodentinária e 
microdureza: estudo in vitro / Nilson Antonio Nunes 
Junior. – Araçatuba, 2022 

32 f. : il.2; tab1. 
 

Dissertação (Mestrado) – Universidade Estadual 
Paulista, Faculdade de Odontologia de Araçatuba 

Orientador: Prof. Alberto Carlos Botazzo Delbem. 
 

1. Clareamento dental 2. Peróxidos 3. Fosfatos 
4. Fluoreto 5. Estética dentária 6. Desmineralização I. T. 

Black D27 
CDD 617.64 



Dedicatória 

À minha mãe, Clavenice Costa Nunes (in memoriam) 

Mãe, três letras para representar a maior e melhor pessoa que já passou em minha 

vida. Quis a vida me dar o privilegio de crescer e viver com minha mãe que sempre foi 

um poço infinito de amor, mesmo quando os puxões de orelha se fizeram necessário, 

aos quais, me nortearam como estudante e homem. Lembro-me do seu sonho em ser 

professora e do quão ficou feliz pelo meu ingresso na faculdade. Por mais que doa não 

poder apertar sua mão na formatura, eu quero que saiba que suas sementes continuam 

crescendo, pois ser mãe é ser professora. 

Te amo ! 



Agradecimentos 
 

 

Ao meu pai, Nilson Antonio Nunes, 
 

A você, minha eterna gratidão. Obrigado por acreditar e confiar que eu poderia ir mais 

longe. Obrigado por ter me educado, apoiado meus sonhos e permitir que ele se 

tornasse realidade. Estaremos sempre juntos, pai. 

 
 

À minha namorada Haruê, 
 

Agradeço por ser companheira, inteligente, simpática, estar sempre pronta para me 

ajudar e por estar comigo nos momentos difíceis (infelizmente não foram poucos) e nos 

momentos de alegria. Sou muito grato por tê-la em minha vida e assim espero ter pelo 

resto dela. Saiba que te amo muito e com você ao meu lado tenho confiança para buscar 

novas conquistas. Você é muito importante em minha vida, sempre será a minha 

primavera, “till the end”. 

 
 

À minha família, 
 

Agradeço a todo o apoio que minhas irmãs (Luciana, Luceime, Nilciane), sobrinhos 

(Luigi, Lucca, Leon) e sobrinhas (Alice, Sofia) sempre me deram na vida e nos estudos. 

Ohana! 

 
 

Ao meu orientador Professor Alberto Carlos Botazzo Delbem, 
 

Agradeço ao digníssimo professor pela oportunidade de poder trabalhar neste 

departamento tão bem equipado e organizado em nossa faculdade. Obrigado pelos 

ensinamentos sem com poucas palavras pois os sábios são assim, não precisam de 

muitas palavras para ensinar. Agradeço por sempre estar pronto para nos ajudar e por 

ter muita, mas muita paciência comigo. És um professor de ímpar admiração entre nós 

alunos. 



À Amanda Scapin e Lívia Valentim, 
 

Obrigado por todo apoio que me deram nos experimentos. Grandes amizades que o 

mestrado me proporcionou. Torço pelo sucesso de vocês! 

 
 

Ao meu amigo Gabriel Pereira Nunes, 
 

Dizem que quem encontra um amigo encontra um tesouro, então “Gabs”, você é uma 

pessoa de ouro. Fico abismado em ver como uma pessoa de ímpar inteligência 

consegue ter um coração tão bondoso e altuísta. Agradeço imensamente em poder ter 

vivido com você durante a moradia, graduação e agora no mestrado. O seu poder de 

transformação na vida das pessoas é algo gigantesco. Graças a sua ajuda pude buscar 

vôos maiores. Saiba que sempre poderá contar comigo! Tenho muito orgulho da pessoa 

que você é e sei que você vai longe nessa vida. “TMJ, Gabs”. 

 
 

À Faculdade de Odontologia de Araçatuba-UNESP, na pessoa dos professores Dr. 

Glauco Issamu Miyahara, digníssimo Diretor e Dr. Alberto Carlos Botazzo Delbem, 

digníssimo Vice-Diretor. 

 
 

Ao Curso de Pós-Graduação em Ciência Odontológica da Faculdade de 

Odontologia de Araçatuba-UNESP, na pessoa do Coordenador Prof. Adj. Juliano 

Pelim Pessan; 

 
 

 
A seção de Pós-Graduação, 

 
Cristiane, Lilian e Valéria, muito obrigada por toda atenção e paciência. 



 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Em todas as coisas o sucesso depende de uma preparação 

prévia, e sem tal preparação o falhanço é certo. 

Confúcio 



Nunes Junior, NA. Efeito de um novo agente clareador contendo hexametafosfato e  

fluoreto sobre a eficácia clareadora, difusão trans-amelodentinária e microdureza: estudo  

in vitro. 2022 32f. Dissertação (Mestrado) - Faculdade de Odontologia, Universidade Estadual 

Paulista, Araçatuba 2022. 

 

RESUMO 

 
 

Este estudo avaliou os efeitos do gluconato de cálcio (CaGlu), fluoreto de sódio (NaF), 

hexametafosfato de sódio (HMP) e NaF / HMP quando adicionado a um gel clareador de 

peróxido de hidrogênio a 35% (H2O2) na alteração de cor, dureza do esmalte e difusão trans- 

amelodentinária. Discos de esmalte / dentina bovino (n = 150) foram divididos de acordo com 

o gel clareador: 35% H2O2 (H2O2); 35% de H2O2 + 0,1% NaF (H2O2/NaF); 35% de H2O2 + 1% 

de HMP (H2O2/HMP); 35% de H2O2+ 0,1% NaF + 1% de HMP (H2O2/NaF/HMP) e 35%  

H2O2+ 2% CaGlu (H2O2/Caglu). Os géis clareadores foram aplicados três vezes (40 min / 

sessão) em intervalos de 7 dias entre cada aplicação. Então, a alteração de cor (ΔE), índice de 

clareamento (ΔWID), porcentagem de perda de dureza superficial (%SH), dureza transversal 

(ΔKHN) e difusão transamelodentinária foram determinadas. Os dados foram submetidos à 

ANOVA, seguida do teste de Student-Newman-Keuls (p<0,05). Todos os géis clareadores 

apresentaram alterações de cor significativas após o tratamento (p<0,001). ΔE e ΔWID foram 

similares entre os geis avaliados. A perda mineral (%SH e ΔKHN) e a difusão 

transamelodentinarária de peróxido de hidrogênio foram menores para o grupo 35% 

H2O2/NaF/HMP; já o grupo H2O2/CaGlu apresentou os maiores valores em relação aos demais   

grupos (p <0,001). Concluiu-se que, a adição de NaF / HMP ao agente clareador de consultório  

não interferiu na eficácia do clareamento, reduziu a desmineralização do esmalte e a difusão de  

H2O2. 

 
Palavras-chave: Clareamento dentário; Peróxidos; Fosfato; Fluoreto; Estética Dentária; 

Desmineralização. 



Nunes Junior, NA. Evaluation of the bleaching efficacy, microhardness and trans-dentinal 

difussion of a new bleaching agent for in-office technique containing hexametaphosphate 

and fluoride. 2022 32f. Dissertação (Mestrado) - Faculdade de Odontologia, Universidade 

Estadual Paulista, Araçatuba 2022. 

 
ABSTRACT 

 

Objective: This study evaluated in vitro the effects of calcium gluconate (CaGlu), sodium 

fluoride (NaF), sodium hexametaphosphate (HMP), and NaF/TMP added to a 35% hydrogen 

peroxide (H2O2) bleaching gel on the color change, enamel hardness and trans-amelodentinal 

diffusion. Enamel discs / bovine dentin (n = 150) were divided according to the bleaching gel: 

35% H2O2 (H2O2); 35% H2O2 + 0.1% NaF (H2O2/NaF); 35% H2O2 + 1% HMP (H2O2/HMP); 

35% H2O2 + 0.1% NaF + 1% HMP (H2O2/NaF/HMP) and 35% H2O2 + 2% CaGlu 

(H2O2/Caglu). The bleaching gels were applied three times (40 min/session) at 7-day intervals 

between each application. Then, color alteration (ΔE), whitening index (ΔWID), percentage of 

surface hardness loss (% SH), cross-sectional hardness (ΔKHN), and trans-amelodentinal 

diffusion were determined. Data were submitted to ANOVA, followed by the Student-

Newman-Keuls test (p <0.05). All bleaching gels showed significant color changes after 

treatment (p <0.001). ΔE and ΔWID were similar among the evaluated gels. Mineral loss (% SH 

and ΔKHN) and trans-amelodentinal diffusion of hydrogen peroxide were lower for 

H2O2/NaF/HMP; the H2O2/CaGlu group presented the highest values about the other groups (p 

<0.001). It is possible to conclude that the addition of NaF/HMP to the in-office bleaching agent 

did not interfere with the bleaching efficacy and reduced enamel demineralization and H2O2 

diffusion.  

 
Keywords: Tooth Bleaching; Peroxides; Phosphate; Fluoride; Esthetics; Desmineralization. 



LISTA DE ABREVIATURAS 
 

 
APC Artificial pulp chamber 

°C Degrees Celsius 

CaGlu Calcium gluconate 

Ca+2 Calcium ion 

CaF+
 Calcium fluoride ion 

Ca(NO3)2 4H2O Calcium nitrate tetrahydrate 

CIE Commission internationale de I’éclairage 

F Fluoride 

HMP Sodium hexametaphosphate 

IA 

KCl 

Integrated area 

potassium chloride 

KHN Knoop hardness unit 

H2O Water 

H2O2 Hydrogen peroxide 

min Minutes 

mg Milligram 

ml Milliliter 

mm Millimeter 

mmol/l Milimol per liter 

Mol/l Mol per liter 

NaF Sodium Fluoride 

NaOH Sodium hydroxide 

NaH2PO4.H2O Sodium phosphate monobasic monohydrate 

nm Nanometers 

pH Hydrogen potential 

ROSs Reative oxygen species 

s Seconds 

SHi Initial surface hardness 

SHf Final surface hardness 

% SH Percentage of loss surface hardness 

TMP Sodium trimetaphosphate 



SUMÁRIO 
 
 
 

1. Introduction…………………...................................................................................... 12 

2. Materials and Methods……........................................................................................ 13 

2.1. Formulation of bleaching gels and determination of experimental 

groups………................................................................................................................. 

 
13 

2.2. Color alteration analysis……………………………………………………………….. 13 

2.2.1. Preparation and pigmentation of enamel/ dentin disc………………..… 13 

2.2.2. Whitening gel treatments and color change measurement…………..… 13 

2.2.3. Calculation of total color change and whiteness index for dentistry….. 14 

2.3. Surface and longitudinal hardness analysis……………………………………….... 14 

2.4. Determination of trans-amelodentinal diffusion of H2O2………….………………. 14 

2.5. Statistical analysis………………………………………………………………………. 15 

3. Results…....................................................................................................................... 16 

4. Discussion ..................................................................................................................... 16 

5. Conclusion..................................................................................................................... 19 

6.References...................................................................................................................... 20 

7. Anexo............................................................................................................................. 29 



12  

1. Introduction 

Beauty is a combination of qualities that arouses admiration through the senses, especially 

vision. One of the main ways to express it is through a smile [1]. The appearance of a smile is associated 

with self-confidence and social interactions [2]. So, tooth whitening is very required in dental clinics 

[3]. In the in-office technique, a bleaching agent with a high concentration (35-38%) of hydrogen 

peroxide (H2O2) is used. It is known that the higher the concentration of H2O2 and the longer the 

exposure time of the dental tissue to the bleaching product [4,5], the greater the release of reactive 

oxygen species and their effects on hard tissues and pulp. Some studies report that bleaching can cause 

demineralization in teeth that undergo the procedure, as well as a decrease in enamel hardness [6-8]. 

On the other hand, studies show that bleaching does not cause any structural changes to the enamel 

[5,9]. However, even with the scientific evidence pointed out, the in-office bleaching aesthetic 

treatment with a high concentration of H2O2 gel is still the most used one by clinicians and preferred 

by patients [3,10]. 

Thus, there is a need to seed strategies and adopt new dosages that minimize these undesirable 

effects resulting from the bleaching procedure. Alternatives have been used, such as the use of cyclic 

phosphates in the composition of the bleaching gel [8,11,12]. The addition of sodium trimetaphosphate 

(TMP) in the bleaching gel led to less enamel demineralization, H2O2 diffusion, and cytotoxicity [8,11]. 

Sodium hexametaphosphate (HMP) is another cyclophosphate that has 3 more phosphates sites in its 

structure than TMP and thus may result in a greater reduction of adverse effects resulting from 

bleaching therapy. In addition, it was observed that HMP reduces the diffusion of H+ ions in the dental 

enamel since it retains this ion in its structure, which also minimizes the propagation of acid in the 

enamel, contributing to reducing the demineralization process of dental tissues [13,14]. 

In vitro studies have shown that the effects of the association of HMP and sodium fluoride 

(NaF) depend on the molar proportion between these compounds [14-16]. Therefore, the ideal 

concentration of HMP to be used is 1% in toothpaste formulations containing 1100 ppm NaF [14,15]. 

In addition, several studies have shown that the association of this salt with NaF helps to inhibit 

demineralization and favors the process of remineralization of dental substrates [15,16]. 

Thus, it is expected that HMP can reduce enamel demineralization and favor the 

remineralization process [16], as well as reduce H2O2 diffusion, in an attempt to minimize the potential 

adverse effects of bleaching dental. Therefore, the objective of this study was to evaluate, in vitro, the 

effects of calcium gluconate (CaGlu), sodium fluoride (NaF), sodium hexametaphosphate (HMP), and 

NaF/TMP added to a 35% hydrogen peroxide (H2O2) bleaching gel on the color change, enamel 

hardness and trans-amelodentinal diffusion. The null hypothesis of the study was that bleaching gels 

containing 35% H2O2 and NaF/HMP or CaGlu do not show a difference in promoting bleaching effect 



13  

and in reducing mineral loss and trans-amelodentinal diffusion compared with bleaching gel containing 

only 35% H2O2.  

 

2. Materials and Methods 

2.1. Formulation of bleaching gels and determination of experimental groups 

The bleaching gels were prepared in each application session since there were no stabilizers 

in their composition. The basic components of the gels were comprised of thickener (12% Carbopol), 

bleaching agent (35% H2O2), glycerin and water (qs) and NaOH required to maintain a pH of 

approximately 7.0. Depending on the experimental group, 0,1% sodium fluoride (NaF) and/or 1% 

sodium hexametaphosphate (HMP) was added [14,15]. A commercial (marketplace) bleaching gel 

containing 35% H2O2 and 2% calcium gluconate (CaGlu), neutral pH (Whiteness HP Blue, FGM, 

Joinville, SC, Brazil) was used as the positive control. Thus, five experimental bleaching gels were 

defined: 1) 35% hydrogen peroxide (H2O2); 2) H2O2+ 0.1% NaF (H2O2/NaF); 3) H2O 2+ 1% HMP 

(H2O2/HMP); 4) H2O2+ 0.1% NaF + 1% HMP (H2O2/NaF/HMP); 5) H2O2 + 2% calcium gluconate 

(H2O2/CaGlu). The sample size per group was 10 enamel/dentin discs, which was based on a previous 

study [8], adopting surface and cross-sectional hardness as primary outcomes, mean the difference 

between groups (9 and 3500, respectively), standard deviation (5 and 2000, respectively) an α error 

of 5% and a β error of 10%. Disks were randomly divided (Excel, Microsoft Corporation, USA) 

among the 5 experimental groups (n = 10). 

2.2. Color alteration analysis 

2.2.1. Preparation and pigmentation of enamel/ dentin discs 

Enamel/ dentin discs (5.7 mm diameter x 3.5 mm thick) were obtained from bovine incisor 

teeth using an 8 mm diameter grinding wheel under water cooling (4º C). Then, the discs were cleaned 

in deionized water and stored in a physiological saline solution containing 0,1% thymol at 4°C [8]. 

After the initial reading of the color values, determined according to the Commissione 

Internationale de I'Eclairage (CIE L* a* b* color system), the discs were stored in microtubes (Kasvi 

K6-0150, 1.5 mL, São José dos Pinhais, PR, Brazil) containing 1 mL of room temperature black tea 

infusion for pigmentation. The infusion was made with 1.6 g of black tea (Chá Matte Leão, Curitiba, 

PR, Brazil) for every 100 mL of deionized water [17]. The pigmentation process was monitored for 

6 days, and the infusion was changed daily. Then, a new reading of the color values was determined 

by the CIE L* a* b* [8, 17]. 

2.2.2. Bleaching gel treatments and color alteration measurement 

After pigmentation, bleaching gels were applied to the enamel surface (0.04 mL) for 40 min, 



14  

using a dosing syringe and a microbrush (KG Sorensen, Cotia, SP, Brazil). For 14 days, 3 bleaching 

sessions were performed at 7-day intervals. The gels were removed with gauze, followed by washing 

with deionized water for 30 s. Between bleaching sessions, the discs were kept in individual plastic 

containers containing 2 mL of artificial saliva (1,5 mmol/L of Ca (NO3)2.H2O; 0,9 mmol/L of 

NaH2PO4.H2O; 150 mmol/L de KCl; in 0.1 mol/L of sodium cacodylate buffer, pH 7.0); and renewed 

every day [8]. 

2.2.3. Calculation of total color alteration and whiteness index for dentistry 

The enamel/ dentin discs were fixed in black silicone supports with a diameter of 5.7 mm and 

a thickness of 3.5 mm, standardizing the incidence of the light beam in the Visible Ultraviolet 

Reflection (UV-2450 Model, Shimadzu, Kyoto, Japan), with wavelength ranging from 400 nm to 700 

nm, under standard lighting D65 and an illumination/observation angle of 45/0°. The measurement 

of colors was performed on the vestibular surface of the enamel after preparation of the discs and 

their pigmentation, 1st, 2nd, and 3rd bleaching sessions, as well as on the 7th and 14th days after the end 

of bleaching. Then, the absolute differences (Δ) of the colors coordinates (L*, a*, b*) were calculated 

between the time analysis (post-staining, post-bleaching, and after 7 and 14 days) and the initial 

values: ΔL* (positive value indicates more brightness, a negative value indicates darker), Δa* 

(positive value indicates redder, a negative value indicates more green) and Δb* (positive value 

indicates more yellow, negative indicates more blue). To determine the total color change between 

the three coordinates, the following formula was used: ΔE = [(ΔL*)2 + (Δa*) 2 + (Δb*)2]1/2 [8, 17]. 

Subsequently, the whiteness index for dentistry (WID) was determined according to the following 

equation: ΔWID = 0.511 L* – 2.324a* – 1.100b* [18]. 

2.3. Surface and cross-sectional hardness analysis 

The enamel surface of the enamel/dentin discs was flattened and polished, to remove 

approximately 120 µm of the surface enamel, according to a previous study [8]. After polishing, five 

impressions, 100 μm equidistant from each other, were made (initial surface hardness: SHi) using a 

Knoop diamond tip under 25 g for 10 s (Micromet 5114, Buehler, Lake Bluff, IL, USA) [13,16]. 

Enamel/dentin discs, with SHi values between 342.0 and 378.0 KH, were randomly distributed 

(Excel, Microsoft Corporation, USA) in the 5 previously defined experimental groups (n = 10). After 

the 3 bleaching sessions, as described above, the final surface hardness (SHf) was determined to 

calculate the percentage change in surface hardness (% SH = [[SHf – SHi] / SHi] × 100) [8]. After 

SHf determination, the enamel/ dentin discs were sectioned in half, and one of the halves was 

embedded in acrylic resin and polished [8]. Knoop hardness in the cross-sectional was determined 

with a load of 5 g/10 s at 5, 10, 15, 20, 25, 30, 40, 50, 60, 80, 100, 120, 140, 160 e 180 μm from the 



15  

surface. The integrated area (AI) under the curve of hardness values (KHN × μm) was calculated by 

the trapezoidal rule using the software GraphPad Prism (Prism 7 for Windows, version 7.00, San 

Diego, CA, USA) [8].   

2.4. Determination of trans-amelodentinal diffusion of H2O2 

To quantify the amount of H2O2 that permeated the dental tissues, enamel/dentin discs (n = 

10/group) were placed in an artificial pulp chamber (APC) between two silicone rings (5.60 mm 

internal diameter; 1.78 mm thick; Ref. OR 008 - Rodimar Rolamentos Ltda, Araraquara, SP, Brazil) 

and sealed with melted pink wax nº 7 (Wilson®, Polidental, Cotia, SP, Brazil) restricting the lateral 

penetration of the bleaching agent, according to a study by Briso et al. [19]. CPAs were placed 

individually in 24-well cell culture plates (Costar Corp., Cambridge, MA, USA). Each well was filled 

with 1 mL of sodium acetate buffer solution (2.0 mol/L, pH 4.5 by acetic acid, Sigma Chemical Co, 

St Louis, MO, USA) and subsequently received the APCs, already containing the disks of 

enamel/dentin. Thus, the dentin surface remained in contact with the acetate solution during the 

bleaching protocol, where the bleaching gels were applied once as described above (item 2.2.2) [19]. 

Then, the amount of 500 μL of buffer solution plus extract was transferred to experimental tubes to 

react with leuco-crystal violet (0.5 mg/mL; Sigma Chemical Co, St Louis, MO, USA) and horseradish 

peroxidase enzyme (1 mg/mL; Sigma Chemical Co, St Louis, MO, USA) [19]. The final reaction 

volume was adjusted to 3 mL with deionized water inserted into a cuvette and the optical density of 

the solutions was measured at a wavelength of 596 nm (UV-2450, Shimadzu, Kyoto, Japan) [20]. A 

standard curve (0.5–5.0 μg/mL) was used to convert the optical density obtained in the samples into 

lg/mL of H2O2.  

2.5. Statistical analysis 

The Sigmaplot® for Windows version 12.0 statistical program was used, with a significance 

level of 5%. For the color alteration data, the different bleaching gels and the time of analysis were 

considered as variation factors and, as variables, the parameters ΔE and ΔWID. The data were 

homogeneous and submitted to analysis of variance (ANOVA) of repeated measurements, followed 

by the Student-Newman-Keuls multiple comparison test. For the analysis of the hardness and 

diffusion of H2O2, the values were considered as variables and the bleaching gels as a factor of 

variation. The values were homogeneous and were submitted to one-way ANOVA followed by the 

Student-Newman-Keuls test. 

 

 

 



16  

3. Results 

The bleaching agents evaluated promoted a significant change in ΔE after bleaching sessions 

(p<0.001) in previously pigmented enamel. All treatments showed similar performance, regardless of 

the period evaluated (p>0.05). The color change was progressive and continuous from the first 

bleaching session (Fig. 1A). In ΔWID, all groups promoted gradual and continuous color changes 

after the bleaching sessions, making the samples whiter (p<0.001). Only the 35% H2O2 group showed 

significant partial regression in whiteness values 14 days after the bleaching procedures (p<0.05) 

(Fig. 1B). 

All bleaching gels led to hardness loss (Table 1) and the greatest hardness loss was 

approximately between 0 and 40 μm enamel depths for all groups tested (Fig. 2). Compared to the 

35% H2O2 group, the addition of NaF reduced the loss of surface hardness (SHf: p <0.001; %SH: p 

<0.001), and CaGlu had the highest losses on the surface and inside the enamel. The bleaching gel 

containing 35% H2O2/NaF/HMP led to the lowest hardness loss values (SHf: p <0.001; %SH: p 

<0.001; KHN × µm: p <0.001; respectively) followed by H2O2/NaF (Table 1). Furthermore, it can be 

noted that the hardness values, as a function of depth, were higher for the H2O2/NaF/HMP group 

(Fig.2). The bleaching gels H2O2/NaF and H2O2/CaGlu showed the highest values of trans-

amelodentinal diffusion of H2O2 and the 35% H2O2/NaF/HMP group had the lowest value (p <0.001). 

 

4. Discussion 

Currently, new bleaching dosages are being developed to minimize the adverse effects of this 

therapy without interfering with its clinical effectiveness. In the present study, the addition of 

remineralizing agents CaGlu, NaF, HMP, and NaF/TMP did not change the aesthetic efficacy of the 

bleaching gel at 35% H2O2, thus the first null hypothesis was accepted; however, the presence of 

NaF/HMP in the gel it reduced mineral loss and trans-amelodentinal diffusion of H2O2, therefore 

these null hypotheses were rejected. 

It has been suggested that ∆E* values above 3.3 show clinically perceptible color changes 

[21,22]. ΔE values between 3 and 8 are moderately visible and above 8 are extremely noticeable [23]. 

According to this parameter, in the present study, all evaluated gels showed clinically relevant color 

change after the adopted bleaching protocol. Several trials have shown that traditional in-office tooth 

bleaching therapies using agents with high concentrations of H2O2 for 30 to 45 minutes produce an 

intense change in tooth color already in the first clinical session and less chromatic changes in 

subsequent sessions [8,24]. According to Sun [25], this occurs because the darker molecules react 

more easily with free radicals, causing a great visual impact in the first application of tooth whitening 



17  

with a high concentration agent. 

 Postoperative color stability is as important as the ability to lighten during treatment. 

Throughout the post-treatment period (7 and 14 days), there was the maintenance of color for all 

bleaching gels evaluated. According to Bizhang et al. [26], color degradation is minimal and linear 

over time, showing adequate color stability after the end of treatment at 18 months. The bleaching 

effectiveness, as well as its maintenance, is derived from a large diffusion of H2O2 in the enamel 

prisms and reaction with the chromophore molecules, resulting in greater reflection and less 

absorption of light [27]. The dental whitening index (ΔWID) indicates that higher values correspond 

to whiter teeth, and lower ΔWID (including negative values) denotes darker teeth. Positive ΔWID 

results for all groups indicated the bleaching ability of the agents [18], and no differences were 

observed between the experimental groups after 14 days of bleaching completion (chromatic 

stabilization). Although ΔE is an important parameter to observe color changes based on L*, a *, b * 

parameters, we must keep in mind that it should not be interpreted individually, but together with 

other variables, such as ΔWID, which correlates color with the proximity of white [18]. 

These data are important, given the great interest and expectation of the patient when seeking 

the bleaching procedure [28]. The improvement of the chromatic and aesthetic characteristics of the 

teeth has been required since the introduction of whitening agents in the dental clinic [2,28] and is 

associated with beauty, engagement, and social and mental well-being, positively impacting the 

patient's self-perception and quality of life [2]. Furthermore, it is reported that disadvantages 

experienced by a person due to cosmetic dental problems may profoundly affect their self-esteem, 

interactions, environmental adaptations, personal relationships, job opportunities, and other 

fundamental aspects affecting their quality of life [29]. Thus, it is essentially fundamental to maintain 

the functional properties and clinical effectiveness of the bleaching gel when adding and/or changing 

its chemical composition. 

 Overall, the results of the color analysis suggest that, even with the addition of NaF and/or 

HMP agents, H2O2 was able to diffuse through enamel and dentin and react with the organic and 

bioorganic matter, or biological waste products from dental tissues, and provide lightning through the 

oxidation of pigments. It is worth mentioning that, although promoting a similar whitening effect, the 

addition of NaF and HMP in the bleaching gel reduced the trans-amelodentinal H2O2 diffusion (Table 

1). Thus, possibly the number of reactive oxygen species released was lower than for the groups 

without NaF/HMP, which hypothesizes that clinically it could culminate in lower postoperative 

sensitivity. 

On the other hand, all the gels evaluated in the present study negatively affected the enamel 

microhardness, promoting its decrease. This is mainly justified because the decomposition products 



18  

of H2O2 not only react with the dark-colored chromophore molecules but also with the organic ones 

(such as proteins, lipids, and substances that stain teeth) and inorganic components of enamel [30]. 

However, the group exposed to the bleaching gel containing NaF/HMP had the highest KHN values, 

which were higher than the other gels evaluated. In addition, it was the only group that showed a loss 

of surface hardness within the acceptable range recommended by the ISO 28399 standard [31]. In 

addition to this, the presence of NaF/HMP in the bleaching gel can also protect the enamel against 

deep mineral loss (Fig. 2). This result is mainly attributed to the synergistic effect resulting from the 

association NaF/HMP incorporated in the bleaching agent. 

It is noteworthy that HMP forms strong complexes with metal ions [32,33] in the oral 

environment, which adsorbs to the enamel surface and retains the charged ions CaF+ and Ca2+ through 

Na+ substitution in the cyclic structure, leading to a reticular formation [34] through the binding of 

Ca2+ to one or more HMP molecules. Through these multiple bonds, the HMP molecules form a layer 

of condensed phosphates, altering the selective permeability of enamel [35] and, in this case, 

increasing the selectivity to cations. Furthermore, HMP is a negatively charged cyclic phosphate that 

leads to a greater amount of electron donor sites on the enamel surface and, consequently, increases 

the adsorption of ionic species such as Ca2+, H2PO4
- e CaH2PO4 [13,16,36], which are important for 

increasing the diffusion of fluoride, calcium, and phosphate in enamel. 

Recently, a study showed that HMP adsorption provides more calcium phosphate-binding 

sites and promotes the supersaturation of these ions near the enamel surface [36], which explains the 

ability of HMP to reduce demineralization of this substrate (Table 1; Fig. 2). In addition, the results 

support that the presence of HMP/NaF in the bleaching gel possibly minimizes changes in the organic 

matrix of enamel, since the removal or degradation of the organic matrix of enamel has been shown to 

significantly reduce its mechanical properties [37], as products derived from H2O2 in tooth whitening 

give rise to unstable oxygen free radicals that are capable of inducing structural changes in matrix 

proteins, located between the lenses and in the area of the stem sheath, as well as significant alteration 

of enamel interrod proteins [30]. 

Although even the incorporation of NaF/HMP in the gel minimized changes in hardness, it is 

important to mention that all bleaching gels evaluated promoted a reduction in hardness in-depth, 

especially up to 60 μm from the surface (Fig. 2), a finding that has already been reported in the 

literature [38]. This data reinforces the demineralizing potential that H2O2 exerts on dental enamel, 

since all the gels were manipulated, and the pH was previously adjusted to neutrality (pH = 7.0) to 

avoid biases resulting from acidic pH that could raise doubts about whether enamel effects are 

attributable to peroxide action or acid etching secondary to the product's low pH value [5]. In addition, 

the adoption of a protocol with a high exposure time and with three sessions of bleaching agent 



19  

application caused a greater loss of hardness.  

Regarding the presence of the other remineralizing agents tested (NaF and CaGlu), there was 

no decrease in H2O2 diffusion, nor changes in enamel hardness (Table 1). The literature has positive 

antecedents with the addition of these agents in the bleaching gel [7, 31 39]. Possibly, the good results 

observed in these studies with the incorporation of NaF are related to the use of this ion in a higher 

concentration (0.2% -1.1% NaF), since in our study 0.1% NaF was used. As for CaGlu, Vieira et al. 

[7], when using a bleaching gel composed of 2% CaGlu, reported a reduction in mineral loss, unlike 

the data of the present study and other works reported in the literature [8,31,40]. According to 

previous studies [39,41], CaGlu is incompatible with strong oxidizing agents and cannot be released 

during bleaching decomposition. 

Thus, it is possible to perform an efficient in-office tooth whitening protocol that is less 

aggressive to mineralized tissues with NaF/HMP supplementation in bleaching gels. However, the 

results should be extrapolated to clinical practice with caution, as in vitro studies have limitations, 

since they do not fully reproduce intra-oral conditions, especially regarding the effect of human saliva 

and the use of fluoride products, such as the daily use of fluoridated toothpaste. Moreover, some 

differences are observed between the laboratory conditions and the natural atmosphere of the oral 

cavity. As well as many other interventions, some discoloration and some continual whitening 

processes can be observed in the natural condition of the oral cavity. Therefore, clinical studies are 

needed to confirm the efficacy of using NaF/HMP in the bleaching agent, as well as the biological 

responses to dental and pulp hard tissues, are necessary to obtain clinical validation of the use of these 

agents as an additive to bleaching gel. 

 

5. Conclusion  

Taking into account the data obtained and the limitations of the experimental model, we can 

conclude that the addition of NaF/HMP to the bleaching gel does not interfere with bleaching efficacy 

and significantly reduces the loss of surface and cross-sectional hardness in enamel, as well as the 

trans-amelodentinal diffusion of H2O2. Thus, future studies should be performed to assess the 

aesthetic outcome and biocompatibility of the different in-office bleaching gels. 

 

Declarations 

Conflict of interest: The authors declare that there is no conflict of interest regarding the publication 

of this paper. 



20  

Funding: This study was financially supported by the Coordenação de Aperfeiçoamento de Pessoal 

de Nivel Superior - Brazil (CAPES) (CAPES, PROCAD/2013 - Proc. 88881.068437/2014–2001) and 

Conselho Nacional de Desenvolvimento Científico e Tecnológico - Brazil (CNPq) (grant number 

312934/2018-1). 

Ethical approval: Not applicable. 

Informed consent: Not applicable. 

 

References 

 

1. Arroyo Cruz G, Orozco Varo A, Montes Luna F, Jiménez-Castellanos E (2021) Esthetic 

assessment of celebrity smiles. J Prosthet Dent.125(1):146-150. doi: 

10.1016/j.prosdent.2019.12.006. 

2. Lukez A, Pavlic A, Trinajstic Zrinski M, Spalj S (2015) The unique contribution of 

elements of smile aesthetics to psychosocial well-being. J Oral Rehabil. 42(4):275-

81. doi: 10.1111/joor.12250. 

3. Vilela AP, Rezende M, Terra RMO, da Silva KL, Sutil E, Calixto AL, Reis A, D 

Loguercio A, Farago PV (2021) Effect of topical application of nanoencapsulated 

eugenol on dental sensitivity reduction after in-office dental bleaching: a randomized, 

triple-blind clinical trial. J Esthet Restor Dent. 33(4):660-667. doi: 

10.1111/jerd.12728. 

4. Benetti F, Gomes-Filho JE, Ferreira LL, Ervolino E, Briso ALF, Araujo GS, Dezan-

Júnior E, Cintra LTA (2017) Hydrogen peroxide induces cell proliferation and 

apoptosis in pulp of rats after dental bleaching in vivo. Arch Oral Biol 81:103-109. 

5. Sa Y, Chen D, Liu Y, Wen W, Xu M, Jiang T, Wang Y (2012) Effects of two in office 

bleaching agents with different pH values on enamel surface structure and color: an 

in situ vs. in vitro study. J Dent 40:26-34. 

6. D'Amario M, D'Attilio M, Baldi M, De Angeli S F, Marzo G, Vadini M,; et al. (2012) 

Histomorphologic alterations of human enamel after repeated applications of a 

bleaching agent. Int J Immunopathol Pharmacol 25:1021-1027. 

7. Vieira I, Vieira-Junior WF, Pauli MC, et al. (2020) Effect of in-office bleaching gels 

with calcium or fluoride on color, roughness, and enamel microhardness. J Clin Exp 

Dent. 12(2):e116-e122. doi:10.4317/jced.56006. 



21  

8. Akabane STF, Danelon M, Nunes GP, et al. (2021) Evaluation of the aesthetic effect, 

enamel microhardness and trans-amelodentinal cytotoxicity of a new bleaching agent 

for professional use containing trimetaphosphate and fluoride. J Mech Behav Biomed 

Mater. 114:104225. doi:10.1016/j.jmbbm.2020.104225. 

9. Sasaki RT, Arcanjo AJ, Flório FM, Basting RT (2009) Micromorphology and 

microhardness of enamel after treatment with home-use bleaching agents containing 

10% carbamide peroxide and 7.5% hydrogen peroxide. J Appl Oral Sci 17:611-616. 

10. de Paula EA, Nava JA, Rosso C, Benazzi CM, Fernandes KT, Kossatz S, Loguercio 

AD, Reis A (2015) In-office bleaching with a two- and seven-day intervals between 

clinical sessions: A randomized clinical trial on tooth sensitivity. J Dent. 43(4):424-9. 

doi: 10.1016/j.jdent.2014.09.009. 

11. Júnior RATP, Danelon M, Pessan JP, et al. (2021) Effect of daily use of fluoridated 

dentifrice and bleaching gels containing calcium, fluoride, or trimetaphosphate on 

enamel hardness: an in vitro study. Clin Oral Investig. 25(3):883-889. 

doi:10.1007/s00784-020-03375-5. 

12. Dos Santos ALE, Delbem ACB, Danelon M, Marcon LN, Shinohara MS (2020) 

Evaluation of new compositions of 10% hydrogen peroxide-based bleaching agents 

containing trimetaphosphate and fluoride on enamel demineralization. Eur J Oral Sci. 

128(5):450-456. doi:10.1111/eos.12735. 

13. Dalpasquale G, Delbem ACB, Pessan JP, Nunes GP, Gorup LF, Neto FNS, de 

Camargo ER, Danelon M (2017) Effect of the addition of nano-sized sodium 

hexametaphosphate to fluoride toothpastes on tooth demineralization: an in vitro 

study. Clin Oral Investig. 21(5):1821-1827. doi: 10.1007/s00784-017-2093-3.  

14. Da Camara DM, Pessan JP, Francati TM, Souza JA, Danelon M, Delbem AC (2016) 

Fluoride toothpaste supplemented with sodium hexametaphosphate reduces enamel 

demineralization in vitro. Clin Oral Investig 20(8):1981-85. 

15. Da Camara DM, Pessan JP, Francati TM, Santos Souza JA, Danelo M, Delbem AC 

(2015) Synergistic effect of fluoride and sodium hexametaphosphate in toothpaste on 

enamel demineralization in situ. J Dent 43(10):1249-54.  

16. Gonçalves FMC, Delbem ACB, Pessan JP, Nunes GP, Emerenciano NG, Garcia LSG, 

Quintero LCB, Neves JG, Danelon M (2018) Remineralizing effect of a fluoridated 

gel containing sodium hexametaphosphate: An in vitro study. Arch Oral Biol 90: 40-

44.  

17. Sulieman M, Addy M, Rees JS (2003) Development and evaluation of a method in 



22  

vitro to study the effectiveness of tooth bleaching. J Dent 31:415-422. 

18. Pérez MM, Ghinea R, Rivas MJ, Yebra A, Ionescu AM, Paravina RD, et al. (2016) 

Development of a customized whiteness index for dentistry based on CIELAB color 

space. Dent Mater. 32(3):461-7. https://doi.org/10.1016/j.dental.2015.12.008. 

19. Briso ALF; Lima APB; Gonçalves RS; Gallinari MO; dos Santos PH (2014) 

Transenamel and transdentinal penetration of hydrogen peroxide applied to cracked 

or microabrasioned enamel. Oper Dent 39:166-173.7 

20. Mottola HA, Simpson BE, Gorin G (1970) Absorptiometric determination of 

hydrogen peroxide in submicrogram amounts with leuco crystal violet and peroxidase 

as catalyst. Anal Chem 42:410-411. 

21. Stober T, Gilde H, Lenz P (2001) Color stability of highly filled composite resin 

materials for facings. Dent Mater. 17(1):87-94. doi: 10.1016/s0109-5641(00)00065-

8. 

22. Vichi A, Ferrari M, Davidson CL (2004) Color and opacity variations in three 

different resin-based composite products after water aging. Dent Mater. 20(6):530-4. 

doi: 10.1016/j.dental.2002.11.001. 

23. Araújo LS, Santos PH, Anchieta RB, Catelan A, Briso ALF, Zaze ACF (2013) 

Mineral loss and color change of enamel after bleaching and staining solutions 

combination. J Biomed Opt. 18:108004–6. 

24. Kossatz S, Dalanhol AP, Cunha T, Loguercio A, Reis A (2011) Effect of light 

activation on tooth sensitivity after in-office bleaching. Oper Dent. 36(3):251-7. doi: 

10.2341/10-289-C. 

25. Sun G. The role of lasers in cosmetic dentistry (2000) Dent Clin North Am. 44(4):831-

850. 

26. Bizhang M, Müller M, Phark JH, Barker ML, Gerlach RW (2007) Clinical trial of 

long-term color stability of hydrogen peroxide strips and sodium percarbonate film. 

Am J Dent. 20 Spec No A:23A-27A. 

27. Kwon YH, Huo MS, Kim KH, Kim SK, Kim YJ (2002) Effects of hydrogen peroxide 

on the light reflectance and morphology of bovine enamel. J Oral Rehabil. 29(5):473-

477. doi:10.1046/j.1365-2842.2002.00856.x 

28. Fiorillo L, Laino L, De Stefano R, D’Amico C, Bocchieri S, Amoroso G, Isola G, 

Cervino G (2019) Dental Whitening Gels: Strengths and Weaknesses of an 

Increasingly Used Method. Gels. 5(3):35. doi:10.3390/gels5030035 

29. Wong AH, Cheung CS, McGrath C (2007) Developing a short form of Oral Health 

https://doi.org/10.1016/j.dental.2015.12.008


23  

Impact Profile (OHIP) for dental aesthetics: OHIP-aesthetic. Community Dent Oral 

Epidemiol. 35(1):64-72. doi:10.1111/j.1600-0528.2007.00330.x 

30. Elfallah HM, Bertassoni LE, Charadram N, Rathsam C, Swain MV (2015) Effect of 

tooth bleaching agents on protein content and mechanical properties of dental enamel. 

Acta Biomater. 20:120-128. doi: 10.1016/j.actbio.2015.03.035. 

31. Torres C, Zanatta RF, Silva TJ, Borges AB (2019) Effect of Calcium and Fluoride 

Addition to Hydrogen Peroxide Bleaching Gel On Tooth Diffusion, Color, and 

Microhardness. Oper Dent. 44(4):424-432. doi: 10.2341/18-113-L. 

32. Andreola F, Castellini E, Manfredini T, Romagnoli M (2004) The role of sodium 

hexametaphosphate in the dissolution process of kaolinite and kaolin. The Journal of 

the European Ceramic Society 24:2113-24. 

33. Cochrane HJ, Saranathan S, Cai F, Cross KJ, Reynolds EC (2008) Enamel subsurface 

lesion remineralisation with casein phosphopeptide stabilised solutions of calcium, 

phosphate and fluoride. Caries Res 42:88-97. 

34. van Wazer JR, Campanella DA (1950) Structure and properties of the condensed 

phosphates. IV. Complex ion formation in polyphosphate solutions. Journal of the 

American Chemical Society 72:655-63. 

35. van Dijk JW, Borggreven JM, Driessens FC (1980) The effect of some phosphates 

and a phosphonate on the electrochemical properties of bovine enamel. Arch Oral Biol 

25:591-595. 

36. Neves JG, Danelon M, Pessan JP, Figueiredo LR, Camargo ER, Delbem ACB (2018) 

Surface free energy of enamel treated with sodium hexametaphosphate, calcium and 

phosphate. Arch Oral Biol. 90:108-112. doi: 10.1016/j.archoralbio.2018.03.008.  

37. Baldassarri M, Margolis HC, Beniash E (2008) Compositional determinants of 

mechanical properties of enamel. J Dent Res. 87(7):645-9. doi: 

10.1177/154405910808700711. 

38. Cavalli V, Rodrigues LK, Paes-Leme AF, Soares LE, Martin AA, Berger SB, Giannini 

M (2011) Effects of the addition of fluoride and calcium to low-concentrated 

carbamide peroxide agents on the enamel surface and subsurface. Photomed Laser 

Surg. 29(5):319-25. doi: 10.1089/pho.2010.2797. 

39. Cavalli V, Rosa DAD, Silva DPD, Kury M, Liporoni PCS, Soares LES, Martins AA 

(2018) Effects of experimental bleaching agents on the mineral content of sound and 

demineralized enamels. J Appl Oral Sci. 4;26:e20170589. doi: 10.1590/1678-7757-

2017-0589. 



24  

40. da Costa Soares MU, Araújo NC, Borges BC, Sales Wda S, Sobral AP (2013) Impact 

of remineralizing agents on enamel microhardness recovery after in-office tooth 

bleaching therapies. Acta Odontol Scand. 71(2):343-8. doi: 

10.3109/00016357.2012.681119. 

41. Furlan IS, Bridi EC, Amaral FLBD, França FMG, Turssi CP, Basting RT (2017) Effect of 

high- or low-concentration bleaching agents containing calcium and/or fluoride on enamel 

microhardness. Gen Dent 65:66–70. 



25  

List of Tables 

 

Table 1.  Mean values (±SD) of initial (SHi) and final (SHf) surface hardness, percentage of loss 

surface hardness (%SH), integrated area (KHN × μm), and trans-amelodentinal penetration of 

H2O2, according to experimental gels (n = 10).  Distinct superscript lowercase letters indicate 

statistical difference among bleaching gels in each variable (Student–Newman–Keuls test, p < 

0.001). 

 

Figure Legends  

 

Figure 1: Mean values (±SD) of total color alteration (∆E) (A) and whitening index in dentistry 

(∆WID) (B) by the International Commission of I'Eclairage (CIE) according to bleaching gels and 

time of analysis (n=10). Distinct superscript lowercase letters indicate statistical difference 

among the bleaching gels at each moment of analysis and among the moments of analysis for 

each bleaching gel (Student-Newman-Keuls; p < 0.05). 

 

Figure 2.  Cross-sectional hardness profiles at different depths in the enamel (n=10) 

according to the bleaching gels 



26  

Table 1. Mean values (SD) of initial (SHi) and final (SHf) surface hardness, percentage of loss 

surface hardness (%SH), integrated area (KHN × μm) and trans-amelodentinal diffusion of 

H2O2, according experimental gels (n = 10).  

Variables 

Bleaching Gels 
 

 

SHi SHf %SH KHN × µm 
H2O2

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Distinct superscript lowercase letters indicate statistical difference among bleaching gels in 

each variable (Student–Newman–Keuls test, p < 0.001). 

 (µg/mL) 

H O 
363.2a 290.1a -20.1a 18,019.1a 6.56a 

2 2 (7.4) (9.2) (1.6) (1,174.8) (0.33) 

H O /NaF 
363.4a

 307.9b -15.3b 18,621.9a 6.99b 
2 2 (7.8) (7.5) (0.8) (633.1) (0.22) 

H O /HMP 
363.4a

 294.8c -18.9c 18,425.6a 6.54a 
2 2 (7.7) (7.8) (1.1) (438.8) (0.58) 

H O /NaF/HMP 
363.3a

 331.6d -8.7d 20,461.8b 6.03c 
2 2 (7.9) (8.5) (1.2) (485.4) (0.57) 

H O /CaGlu 
363.8a

 286.0a -21.4a 17,062.8c 6.75a 
2 2 (7.8) (7.3) (1.5) (784.9) (0.33) 

 



27  

 

 
 

Figure 1. Mean values (±SD) of total color alteration (∆E) (A) and whitening 

index in dentistry (∆WID) (B) by the International Commission of I'Eclairage 

(CIE) according to bleaching gels and time of analysis (n=10). Distinct 

superscript lowercase letters indicate statistical difference among the bleaching 

gels at each moment of analysis and among the moments of analysis for each 

bleaching gel (Student-Newman-Keuls; p < 0.05).



28  

 

 

Figure 2. Cross-sectional hardness profiles at different depths in 

the enamel (n=10) according to the bleaching gels. 



29  

7. Anexo 

 
 

Author Guidelines for Publishing in the Clinical Oral Investigations 

Title Page 

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• Results 

• Conclusions 

• Clinical Relevance 

 
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Headings 



30  

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References 

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examples: 

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• Journal article 



31  

Gamelin FX, Baquet G, Berthoin S, Thevenet D, Nourry C, Nottin S, Bosquet L (2009) Effect 

of high intensity intermittent training on heart rate variability in prepubescent children. Eur J 

Appl Physiol 105:731-738. https://doi.org/10.1007/s00421-008-0955-8 

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329 

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Med. https://doi.org/10.1007/s001090000086 

• Book 

 
South J, Blass B (2001) The future of modern genomics. Blackwell, London 

• Book chapter 

 
Brown B, Aaron M (2001) The politics of nature. In: Smith J (ed) The rise of modern genomics, 

3rd edn. Wiley, New York, pp 230-257 

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Cartwright J (2007) Big stars have weather too. IOP Publishing PhysicsWeb. 

http://physicsweb.org/articles/news/11/6/16/1. Accessed 26 June 2007 

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http://physicsweb.org/articles/news/11/6/16/1


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