Clin Oral InvestDOI 10.1007/s00784-005-0024-1
Stefan-Ioan Stratul . Frank Schwarz . Jürgen Becker . Britta Willershausen . Anton Sculean
Healing of intrabony defects following treatment with an oilycalcium hydroxide suspension (Osteoinductal). A controlledclinical study
Received: 21 July 2005 / Accepted: 25 November 2005
Abstract The purpose of the present clinical study was to
CAL gains (P<0.05) than AFS alone. Within the limits of
evaluate the healing of deep intrabony defects following
the present study, it can be concluded that: (1) at 6 months
the application of an oily calcium hydroxide suspension
after surgery both therapies resulted in statistically signif-
(OCHS). Thirty patients suffering from chronic periodon-
icant PD reductions and CAL gains and (2) treatment with
titis, each of whom displayed one intrabony defect, were
OCHS resulted in statistically significant higher CAL gains
randomly treated with access flap surgery (AFS) and the
application of OCHS (test) or with AFS alone (control). The following clinical parameters were recorded at base-
Keywords Regenerative periodontal therapy . Intrabony
line and at 6 months after therapy: plaque index, gingival
defect . Controlled clinical study . Oily calcium hydroxide
index, bleeding on probing, probing depth (PD), gingival
recession, and clinical attachment level (CAL). No differ-ences in any of the investigated parameters were observedat baseline between the two groups. At 6 months after
therapy, the test group showed a reduction in mean PDfrom 7.7±1.5 to 2.9±0.9 mm (P<0.001) and a change in
A major goal of periodontal treatment is to resolve inflam-
mean CAL from 9.6±2.1 to 5.5±2.5 mm (P<0.001). In the
mation and thereby arrest disease progression ]. The
control group, the mean PD was reduced from 6.9±0.9 to
results from controlled clinical studies have shown that
3.7±0.9 mm (P<0.001) and the mean CAL changed from
nonsurgical treatment and various types of conventional
8.5±2.5 to 6.4±2.7 mm (P<0.001). OCHS resulted in sta-
surgical treatment may lead to clinically important and
tistically significant higher PD reductions (P<0.01) and
statistically significant probing pocket depth reductions andclinical attachment level (CAL) gains , ]. However,histologic studies demonstrated that healing following
S.-I. StratulDepartment of Periodontology,
nonsurgical periodontal therapy and any type of conven-
tional surgical periodontal therapy is mainly characterized
by the formation of a long junctional epithelium along theinstrumented root surfaces and no predictable regeneration
of attachment apparatuses [, ]. Ideally, peri-
Department of Oral Surgery,Heinrich Heine University,
odontal therapy does not only include arresting the disease
but also the regeneration of the tissues that have been lostdue to the disease. This includes de novo formation of
connective tissue attachment, cementum formation, and the
Department of Conservative Dentistry and Periodontology,Johannes-Gutenberg University,
regrowth of alveolar bone []. Several treatment modalities,
such as the use of guided tissue regeneration (GTR) alone orin combination with different types of bone grafts, root
surface demineralization, enamel matrix derivatives (EMDs),
Department of Periodontology,Radboud University Medical Center,
or the application of growth factors, have been employed
with varying degrees of success to predictably accomplish
6500 Nijmegen, Philips van Leydenlaan 25,
calcium hydroxide suspension (OCHS) has also been
supposed to support periodontal regeneration [. Calcium
hydroxide (CH) is a product of lime slaking from quick lime.
The slurry of CH incorporates carbon dioxide from the air
program, and (4) presence of one intrabony defect with a
and hardens with the formation of calcium carbonate and
probing depth (PD) of >6 mm and an intrabony component
water. CH is not soluble in organic acids, has a marginal
of >3 mm as detected on radiographs. All patients
solubility in water and an improved solubility in glycerine or
underwent initial periodontal therapy 1 month prior to
syrup. The saturated aqueous solution exhibits an alkalic pH
surgery. The following clinical parameters were assessed
value of 12.4. Several experimental studies have shown that
1 week prior to and 6 months after the surgical procedure
CH may possess antimicrobial , and anti-inflamma-
using a periodontal probe (PCP 12, Hu-Friedy, Chicago,
tory properties []. When applied on amputated dental pulp
IL, USA): PI gingival index (GI) bleeding on
or into the root canal close to the apex, CH has been reported
probing (BOP), PD, gingival recession (GR), and CAL.
to result in a destruction of the vital tissue, leading to the
The measurements were made at six aspects per tooth:
formation of a necrotic layer and, subsequently, formation of
mesiovestibular, midvestibular, distovestibular, mesiolin-
a hard tissue barrier below the exposure site , ].
gual, midlingual, and distolingual. The cemento–enamel
Additionally, CH also seems to have a positive influence on
junction (CEJ) was used as the reference point. A resto-
the healing of periapical lesions , ]. These effects may
ration margin was used as a reference in cases where the
be mainly due to the alcalic properties of CH leading to a
CEJ was destroyed due to restorations. All measurements
neutralization of the acidic metabolites of macrophages and
were performed by one previously calibrated examiner
osteoclasts ]. However, the CH mechanism used to
who was masked to the specific treatment procedures. The
promote the repair of bone tissues may not only do so by
study reports only measurements at the same deepest PD of
providing rich Ca2+ and alkaline environment mineral
the selected defect. Pre- and postoperative radiographs
deposition, but also by stimulating the calcification enzyme
were taken using the long-cone parallel technique. After
activity of osteoblasts [The oily formulation, available
controlling for the depth of the intrabony component and
under the name Osteoinductal (Osteoinductal GmbH,
CAL, all patients were randomly assigned to the following
München, Germany) (OCHS), contains CH, liquid and
treatment groups: (1) AFS and the application of an OCHS
solid carbohydrate chains, and fatty acids (myristaleinic,
(Osteoinductal, Osteoinductal GmbH, München, Ger-
oleic, palmitoleinic, gadoleinic, margaric, pentadecanic,
many) (test) and (2) AFS alone (control).
myristic, linolenic, stearic, palmitic, arachidic, lauric, andlinolic) esterified with glycerol. The oily parts consist of anatural product of porcine origin-oleum pedum, which was
demonstrated to have a low cytotoxic effect on humanfibroblasts ], and vaselinum album. So far, there are no
All operative procedures were performed under local
data from controlled clinical studies evaluating healing of
anesthesia by the same surgeon. Following intracrevicular
intrabony defects following treatment with OCHS. There-
incisions, full thickness mucoperiosteal flaps were raised
fore, the aim of this controlled clinical study was to evaluate
vestibularly and orally. Vertical releasing incisions were
and compare the healing of advanced intrabony periodontal
performed only if necessary for better access or to achieve
defects following treatment with access flap surgery (AFS)
better closure of the surgical site. All granulation tissue was
and the application of OCHS and AFS alone.
removed from the defects and the roots were thoroughlyscaled and planed using hand and ultrasound instruments. No root surface conditioning was performed. During
surgery the following measurements were made: distancefrom the CEJ to the bottom of the defect (CEJ-BD) and
distance from the CEJ to the most coronal extension of thealveolar bone crest (CEJ-BC). The intrabony component
Thirty patients with chronic periodontitis were included in
(INTRA, BC-BD) of the defects was defined as CEJ-BD
this parallel-design study (i.e., 15 patients in each group).
minus CEJ-BC. At the test sites, bleeding into the defects
The patient population comprised 20 men and 10 women
was reduced to a minimum and the sites were subsequently
(mean age=43±15 years). Patients who reported to smoke
filled with OCHS, starting from the bottom of the defect.
only occasionally were not considered as smokers
Care was taken to obtain direct contact between OCHS and
According to the given definition there were no smokers
the adjacent alveolar bone without interposition of a blood
included in the present study. The study was in accordance
clot. Defects were slightly overfilled, as the OCHS has a
with the Helsinki Declaration of 1975, as revised in 1983
creamy consistency and tends to leak from the defect.
and all participants signed informed consent forms. The
Finally, the mucoperiosteal flaps were repositioned cor-
study protocol was approved by the Ethical Committee of
onally and fixed with vertical or horizontal mattress
the Victor Babes University of Medicine and Pharmacy of
sutures. Where possible, sutures were put in position
Timisoara, Romania. Criteria needed for inclusion were:
before filling the defects with the OCHS to prevent the
(1) no systemic diseases that could influence the outcome
possible leakage of the material. The same surgical
of the therapy, (2) a good level of oral hygiene [plaque
protocol was also used for the control sites; however, the
index (PI) <1] (3) compliance with the maintenance
Table 1 Configuration and distribution of the treated defects
Table 4 Clinical parameters at baseline and 6 months after surgeryfor the test and control groups (n=15 patients in each group)
Table 2 Baseline defect characteristics (mean±SD)
All patients received peri- and postoperative antibiotic
power (1-β) of 0.75 was computed for a two-sided null
medication for 1 week (3× 500 mg amoxicillin/day). Addi-
tionally, postoperative care consisted of rinsing with 0.2%chlorhexidine (PlakOut, Santa Balanos, Greece) twice a dayfor 4 weeks. The sutures were removed 14 days after the
surgery. Recall appointments were scheduled every secondweek during the first 2 months after surgery and monthly
At the baseline examination, there were no statistically
following the rest of the observation period. Neither
significant differences in any of the investigated param-
probing nor subgingival instrumentation was performed
eters. The configuration of the defects is shown in Table
during the first 6 months after the surgery.
The depth of the intrabony component as measured duringsurgery is presented in Table The postoperative healingwas uneventful in both groups. No complications, such as
allergic reactions, abscesses, or infections, were observedthroughout the study period. However, minor postoperative
The statistical analysis was performed using a commer-
swelling appeared to be reduced in the test group as
cially available software program [Statistical Package for
compared to the control group. The mean PI, GI, and BOP
the Social Sciences (SPSS) 11.0, SPSS, Chicago, IL,
for both groups at baseline and after 6 months are
USA]. The primary outcome variable was CAL. In the
summarized in Table . In both groups, mean PI values
calculations, only the deepest PD per tooth was taken into
remained low throughout the study period. There were no
consideration. For the statistical evaluation of the changes
statistically significant differences within or between
from baseline to 6 months after surgery, the Wilcoxon
groups. In both groups the GI and BOP improvement
signed-rank test was used. For comparisons between the
was statistically significant as compared to the baseline
groups, the Mann–Whitney U test was used. For the given
(P<0.01). However, at 6 months after surgery, the
input values (CAL and SD of both groups, a level of
difference between the groups was statistically not signif-
significance of alpha=0.05, and a sample size of 15), a
icant. The mean PD, GR, and CAL in both groups atbaseline and after 6 months are summarized in Table . In
Table 3 Mean (±SD) PI, GI, and BOP at baseline and after6 months (n=15 patients in each group)
Table 5 Frequency distribution of CAL gain in the test and controlgroups (n=15 patients in each group)
particular, at 6 months after therapy, the test group showed
gen) with 3.6±1.5 mm. In particular, CAL gains of 2–3 mm
a reduction in mean PD from 7.7±1.5 to 2.9±0.9 mm
were observed in 29.2% of the defects, while CAL gains of
(P<0.001), and a change in mean CAL from 9.6±2.1 to 5.5±
4–5 mm were reported in 35.4% of the defects, and CAL
2.5 mm (P<0.001). In the control group, the mean PD was
gains of 6 mm or more were reported in 24.9% of the defects
reduced from 6.9±0.9 to 3.7±0.9 mm (P<0.001), and the
mean CAL changed from 8.5±2.5 to 6.4±2.7 mm (P<0.001).
group might also be compared with previously published
OCHS resulted in statistically significant higher PD
clinical data on EMD. Hejil et al. reported CAL gains of
reductions (P<0.01) and CAL gains (P<0.05) than AFS
2.1 mm 8 months postoperatively and 2.3 mm 16 months
alone. The frequency distribution of CAL gains in both
postoperatively (baseline CAL=9.4 mm, INTRA=4.8 mm).
treatment groups is shown in Table In particular, in the
There was a statistically significant difference between
test group, 66.6% of the sites (n=10 defects) gained at least
EMD- and placebo-treated sites. Similarly, Pontoriero et al.
4 mm of CAL. In contrast, a CAL gain of 4 mm or more
] reported a mean CAL gain of 2.9 mm for EMD-treated
was measured in four defects (26.7%) in the control group
sites after 1 year, with a statistically significant difference
CAL=9.1 mm, INTRA=4.2 mm); Froum et al. [] reporteda 4.26-mm CAL gain (baseline CAL was not reported,
INTRA=5.63 mm); and Sculean et al. [reported a 3.4-mm CAL gain (baseline CAL=10.6, INTRA=3.8 mm). The
The results of the present study have indicated that treatment
mean CAL gain of 2.1±2.3 mm obtained in the control
of intrabony defects with both OCHS and AFS resulted in
group is also in agreement with most of the reported results
statistically significant and clinically important reductions of
]. However, slight differences noted in these
PD and gains of CAL at 6 months after surgery. However,
data may be explained by baseline defect depths and
the test treatment resulted in statistically significant higher
configurations. Indeed, it is well documented that the
PD reductions and CAL gains than the control treatment.
postoperative PD reduction and CAL gain obtained after any
From a clinical point of view, it should also be noted that
type of conventional or regenerative periodontal treatment is
postoperative healing was uneventful in all patients. Because
dependent upon the initial defect depth (i.e., the deeper the
there were no signs of any allergic reactions, abscesses, or
defect, the higher the CAL gain) [, , In this context,
infections, it might be suggested that OCHS was well
it must also be emphasized that even though mean initial PD,
tolerated. Furthermore, the observation that postoperative
CAL, and INTRA were statistically not significant between
swelling tended to be lower in the OCHS-treated than in the
both groups, mean values tended to be higher in the OCHS
AFS-treated group might be explained by the anti-inflam-
group. Accordingly, it is impossible to estimate to what
matory properties noted for CH [However, one problem
extent this difference might also have influenced the higher
encountered during the surgical procedure was the low
mean CAL gains following the application of OCHS.
consistency of OCHS which in turn might result in the
Nevertheless, the present data seem to indicate that OCHS
mucoperiosteal flap having poor resistance to collapsing into
might be successfully used for treatment of intrabony
the intrabony defect, allowing undesirable cell types to enter
periodontal defects. In this context, however, it is important
the secluded wound area [, Indeed, this flap
to realize that the presented clinical results need to be
collapse may have implications on the outcome of treatment
supported by extended histologic evidence. It is still unclear
in a manner similar to that observed following the ap-
to what extent the CAL gains obtained following application
plication of enamel matrix proteins (EMD) In this
of OCHS represent real periodontal regeneration rather than
context, the collapse may be prevented by means of implan-
defect fill without new connective tissue attachment. Also,
tation of additional bone grafts or bone graft substitutes into
the stability of the obtained CAL gains over time has to be
the defect to support the OCHS in preserving its original
evaluated in further clinical studies.
position. Further studies are necessary to clarify this issue.
Within the limits of the present study, it can be concluded
When interpreting the present results, it has to be noted that
that: (1) at 6 months after surgery both therapies resulted in
mean CAL gain as observed 6 months postoperatively was
statistically significant PD reductions and CAL gains, and
3.9±1.2 mm in the OCHS group and 2.1±2.3 mm in the AFS
(2) treatment with OCHS resulted in statistically significant
group. In this context, it needs to be pointed out that these
higher CAL gains than treatment with AFS alone.
are the first data evaluating the use of OCHS for thetreatment of intrabony periodontal defects. Therefore, acomparison with other studies is not possible. However, the
CAL gains noted in the OCHS group seemed to be withinthe range of other well-documented regenerative treatment
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for centuries are still central to the national identity of we shall be opening a Europe House in Ashgabat. modern-day Turkmens. You can clearly recognize this A further stimulus to our relations is the enormous in our government’s foreign policy based on the prin-potential the EU has in economics and trade, fi nance ciple of positive neutrality, which has been followed and investment,
BREAST REDUCTION POSTOPERATIVE INSTRUCTIONS Management of Pain and Discomfort: We have found through many years of experience that the level of pain and discomfort following breast reduction surgery is far less than you might expect. It is not unusual for our patients to return and tell us that their level of discomfort was far less than they had feared. However, you have been given pain reliever