J. Dent. Ass. S. Afr. Vol. 31, No 10 pp 509-513

The Effects of the Acid Etch and Direct Bonding Technique in 
Orthodontics on Enamel Surface Topography
P L Sadowsky and D H Retief

Department of Orthodontics, University of the Witwatersrand,
Johannesburg and Dental Research Unit of the South African 
Medical Research Council and the University of the Witwatersrand,
Johannesburg, Republic of South Africa.

SUMMARY

The acid etch technique and the direct bonding of 
orthodontic attachments have become accepted 
procedures in clinical orthodontics. Changes are 
produced in enamel surface topography by acid 
etching and on removal of the bonded attachments at 
the end of treatment. These changes were examined 
by scanning electron microscopy and the clinical im­
plications of these surface changes are discussed.

OPSOMMING

In Ortodonsie word die suur-etstegniek en die direkte 
binding van aanhegtings aan tande as aanvaarbare 
kliniese prosedures beskou. Suur-etsing, sowel as die 
verwydering van die aanhegtings na afloop van die 
behandeling, veroorsaak veranderings in die 
oppervlaktopografie van glasuur. Hierdie verande­
rings is deur aftaselektronmikroskopie ondersoek en 
die kliniese implikasies van die waarnemings word 
bespreek.

INTRODUCTION
The added retention afforded by the acid etch 
technique has made the direct bonding of orthodontic 
attachments (Fig. 1) an accepted adjunct in the arma­
mentarium of the orthodontist (Zachrisson, 1975; 
Retief and Sadowsky, 1975). Several resin systems 
have recently become commercially available for the 
direct bonding of plastic and metal attachments and 
different techniques have been developed for the 
placement of the brackets. These all rely on prior 
etching of the enamel surfaces onto which the 
orthodontic attachments are to be bonded.
The purpose of this investigation was to study the 
effects of an etching solution on human enamel sur­
faces and of polishing procedures on etched surfaces. 
In addition, clinical procedures to restore enamel sur­
faces after removal of bonded attachments were 
evaluated.

MATERIALS AND METHODS
Freshly extracted, sound human teeth were used in 
this investigation. The teeth were cleaned and stored 
at -4°C until needed.
Some of the teeth were not etched in order to study 
normal enamel surfaces. The enamel surfaces of a 
number of teeth were etched with 50 percent 
phosphoric acid for two minutes. Some of the etched 
surfaces were polished with a rubber cup and a water 
slurry of pumice for varying time periods. Orthodontic 
attachments were bonded to some of the etched 
enamel surfaces under simulated clinical conditions. 
After allowing the resin to cure for approximately one

Fig. 1. Directly bonded orthodontic attachments.

hour, the bonded attachments were removed by hand 
instruments. Visible remnants of bonding material 
were removed with a dental scaler and the surfaces of 
some of these teeth polished with a rubber cup and a 
water slurry of pumice. A number of these polished 
surfaces were re-etched for two minutes with the 50 
per cent phosphoric acid solution.
Specimens from each of these groups were mounted on 
aluminium stubs and coated with silver in a high 
vacuum evaporator*. They were subsequently viewed 
in a Cambridge S4 Stereoscan scanning electron 
microscope**. The machine was operated at 15 kV and

* Edwards Coating Unit, Edwards High Vacuum Ltd., Crawley, 
Sussex, England.

** Cambridge Scientific Instruments Ltd., Cambridge, England.

Journal of the D.A.S.A. -  October 1976 509



P L Sadowsky and D H Retief

Fig. 2 Sound human enamel. SEM X 2000. Fig. 3. Human enamel etched with 50% phosphoric acid for 2 
minutes. SEM X 2000.

Fig. 4. Etched enamel mechanically polished for approximate­
ly 2 seconds. SEM X 2000. Fi*- S. Etched enamel mechanically polished for approximate­

ly 10 seconds. SEM X 2000.

510 Tydskrif van die T.V.S.A- -  Oktober 1976



ENAMEL SURFACE TOPOGRAPHY

Fig. 6. An enamel surface from which a bonded attachment 
had been removed and the remaining resin removed by 
scaling. SEM X 2000.

Fig. 7. Mechanical polishing for approximately 2 seconds of 
the hand scaled enamel surface after bond removal. 
SEM X 2000.

Fig■ 8 Mechanical polishing for approximately 10 seconds of 
the hand scaled enamel surface after bond removal.
SEM X 2000.

Fig. 9. The enamel appearance after bond removal, hand scal­
ing, mechanical polishing and subsequent phosphoric 
acid re-etching for 2 minutes. SEM X 2000.

Journal of the D.A.S.A. -  October 1976 511



P L Sadowsky and D H Retief

the beam-specimen angle varied to obtain the best 
surface projection.

RESULTS
A normal enamel surface has a relatively featureless 
topography (Fig. 2). An enamel surface which had 
been etched with 50 per cent phosphoric acid for two 
minutes showed the preferential etching action of the 
acid. The prism cores were etched to a greater extent 
than the prism peripheries (Fig. 3). Figures 4 and 5 are 
scanning electron micrographs of etched enamel sur­
faces that had been polished with a rubber cup and 
pumice for varying lengths of time. The former was 
polished for approximately two seconds (Fig. 4) while 
the latter was polished for about 10 seconds (Fig. 5). A 
smoother surface topography was obtained by polish­
ing for a longer period.
The surfaces of the teeth from which the bonded at­
tachments were removed and the visible resin rem­
nants scraped by means of scaling instruments, show­
ed that the normal enamel surface topography was 
obscured by adhering resin (Fig. 6). An appreciable 
amount of resin was left after polishing these surfaces 
with a rubber cup and pumice for two seconds (Fig. 7). 
Polishing for 10 seconds resulted in a smoother sur­
face (Fig. 8).
Fig. 9 is a scanning electron micrograph o f an 
enamel surface from which the bonded attachments 
were removed, the enamel surface scaled and polish­
ed and then re-etched with 50 per cent phosphoric acid 
for two minutes. The exposed enamel surface has been 
etched but the bulk of the surface was covered by resin 
remnants which formed a protective coating against 
the acid attack.

DISCUSSION
The preferential etching of the enamel surface by 50 
per i ent phosphoric acid produces micropores into 
which the curing bonding resin will flow. When cured 
the bonded attachments are mechanically retained to 
the etched surface (Gwinnett and Matsui, 1967).
Etching of the enamel surface leads to a permanent 
loss of superficial enamel. The depth of etch or 
amount of enamel lost is dependent on the acid con­
centration and the duration, of etch (Silverstone, 1974; 
Retief, 1975). Etched enamel surfaces can readily be 
restored to their normal appearance by simple 
polishing procedures (Figs. 4 and 5). This confirms the 
observations previously reported by Newman and 
Facq (1971). In vitro studies by Lenz and Miihlemann 
(1963) of etched enamel surfaces suggested that the 
disappearance of the etching pattern could be due to 
abrasion or remineralization of the etched surfaces. 
Scanning electron microscope examinations of the in 
vivo recovery of etched enamel surfaces showed that 
apparent recovery of the etched surfaces had taken 
place (Lee et al, 1970; Retief, 1973). These studies did 
not prove that remineralization of etched enamel sur­
faces had occurred. Wei (1970) showed by electron

microprobe x-ray spectrophotometry that etched sur­
faces were remineralized in vitro. Lee et al (1972) used 
a similar analytical technique to demonstrate that 
complete remineralization of etched enamel surfaces 
occurred in vivo.
When directly bonded attachments were removed at 
the completion of orthodontic treatment, scaling with 
hand instruments alone to remove the visible rem­
nants of the bonding resin was not sufficient to 
produce a smooth enamel surface (Fig. 6). Further 
polishing with a rubber cup and pumice was required 
to produce an acceptable enamel surface topography 
(Fig. 8). The latter step is necessary to reduce plaque 
and debris accumulation. The time of mechanical 
polishing required will depend on the abrasive pro­
perties of the pumice used, the hand pressure applied 
and the hardness or abrasion resistance of the bon­
ding material.

It has been shown clinically that rebonding after 
loss of a bonded attachment is possible (Retief and 
Sadowsky, 1975). This is probably due to the inflow of 
the bonding resin into the micropores created on a re­
etched surface (Fig. 9) and chemical union between 
the new resin and the resin entrapped in the etched 
enamel surface after failure of a bond.

Concern has been expressed about the acid etch 
technique predisposing the enamel surface to carious 
attack after removal of bonded attachments. It has 
been shown that when the bulk of dental resins was 
removed from etched enamel surfaces, the materials 
which had penetrated the etched surfaces remained in 
situ (Gwinnett, 1971; Miura, Nakagawa and Ishizaki, 
1973; Retief, 1974). Experiments carried out in vitro 
have demonstrated that the encapsulation of enamel 
crystallites by the resins which remained embedded 
within the etched enamel resulted in increased resis­
tance to subsequent demineralization (Gwinnett and 
Matsui, 1967; Silverstone, 1974).

ACKNOWLEDGEMENTS
We wish to thank the staff of the Electron Microscope 
Unit of the University of the Witwatersrand for their 
assistance with the scanning electron microscopy, the 
staff of the Dental Research Unit for printing the 
photomicrographs and Miss B. Slack for typing the 
manuscript.

REFERENCES

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Gwinnett, A.J. & Matsui, A. (1967) A study of enamel adhesives. 
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Lee, H.L. et al. (1972) Sealing of developmental pits and fissures: 
IV. Measurement of in vivo fluoride pickup by electron

512 Tydskrif van die T.V.S.A. -  Oktober 1976



ENAMEL SURFACE TOPOGRAPHY
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Journal of the D.A.S.A. -  October 1976 513