Biological effects of a porcine-derived collagen membrane on intrabony defects

Lee, Chang-Kyun; Koo, Ki-Tae; Kim, Tae-Il; Seol, Yang-Jo; Lee, Yong-Moo; Rhyu, In-Chul; Ku, Young; Chung, Chong-Pyoung; Park, Yoon-Jeong; Lee, Jue-Yeon

doi:10.5051/jpis.2010.40.5.232

J Periodontal Implant Sci. 2010 Oct;40(5):232-238. English.
Published online Oct 31, 2010.
https://doi.org/10.5051/jpis.2010.40.5.232

Original Article

Biological effects of a porcine-derived collagen membrane on intrabony defects

Chang-Kyun Lee,¹ Ki-Tae Koo,¹ Tae-Il Kim

,¹ Yang-Jo Seol

,¹ Yong-Moo Lee,¹ In-Chul Rhyu,¹ Young Ku

,¹ Chong-Pyoung Chung,¹ Yoon-Jeong Park,² and Jue-Yeon Lee³

Author information

Author notes

Copyright and License

- ¹Department of Periodontology and Dental Research Institute, Seoul National University School of Dentistry, Seoul, Korea.
- ²Department of Craniomaxillofacial Reconstructive Sciences, Seoul National University School of Dentistry, Seoul, Korea.
- ³Research Center, Nano Intelligent Biomedical Engineering Corporation, Seoul, Korea.
Correspondence: Chong-Pyoung Chung. Department of Periodontology, Seoul National University School of Dentistry, 28 Yeongeon-dong, Jongno-gu, Seoul 110-749, Korea. Email: ccpperio@snu.ac.kr , Tel: +82-2-2072-2289, Fax: +82-2-744-0051

Received June 22, 2010; Accepted September 09, 2010.

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/).

Abstract

Purpose

To prolong the degradation time of collagen membranes, various cross-linking techniques have been developed. For cross-linking, chemicals such as formaldehyde and glutaraldehyde are added to collagen membranes, but these chemicals could adversely affect surrounding tissues. The aim of this study is to evaluate the ability of porous non-chemical cross-linking porcine-derived collagen nanofibrous membrane to enhance bone and associated tissue regeneration in one-wall intrabony defects in beagle dogs.

Methods

The second and third mandibular premolars and the first molars of 2 adult beagles were extracted bilaterally and the extraction sites were allowed to heal for 10 weeks. One-wall intrabony defects were prepared bilaterally on the mesial and distal side of the fourth mandibular premolars. Among eight defects, four defects were not covered with membrane as controls and the other four defects were covered with membrane as the experimental group. The animals were sacrificed 10 weeks after surgery.

Results

Wound healing was generally uneventful. For all parameters evaluating bone regeneration, the experimental group showed significantly superior results compared to the control. In new bone height (NBh), the experimental group exhibited a greater mean value than the control (3.04 ± 0.23 mm/1.57 ± 0.59, P = 0.003). Also, in new bone area (NBa) and new bone volume (NBv), the experimental group showed superior results compared to the control (NBa, 34.48 ± 10.21% vs. 5.09 ± 5.76%, P = 0.014; and NBv, 28.04 ± 12.96 vs. 1.55 ± 0.57, P = 0.041). On the other hand, for parameters evaluating periodontal tissue regeneration, including junctional epithelium migration and new cementum height, there were no statistically significant differences between two groups.

Conclusions

Within the limitations of this study, this collagen membrane enhanced bone regeneration at one-wall intrabony defects. On the other hand, no influence of this membrane on periodontal tissue regeneration could be ascertained in this study.

Keywords

Absorbable implants; Bone regeneration; Collagen; Guided tissue regeneration

INTRODUCTION

Various treatment modalities have been performed to restore lost periodontal tissue due to periodontitis. First, scaling and root planing are performed to remove local factors such as plaque, calculus and endotoxin. When the inflammatory signs remain at the sites with deep probing pocket depth and alveolar bone defects, periodontal surgery may be necessary.

Periodontal surgeries such as gingivectomy, open flap debridement, modified Widman flap, and osseous surgery are performed to access diseased root surfaces and remove local factors effectively. These procedures result in pocket depth reduction and clinical attachment gain [1-3]. However, these results are usually achieved by the formation of long junctional epithelium without connective tissue attachment or cementum formation [4-6]. This wound healing pattern is considered periodontal repair, not regeneration.

For periodontal regeneration, the gingival epithelium has to be prevented from contacting the root surface during healing. Gottlow et al. [7] showed that a barrier membrane could block the ingrowth of gingival epithelium and connective tissue into periodontal defects.

The guided tissue regeneration (GTR) procedure, in which a barrier membrane is used to exclude soft tissue from the defects, has been shown to partially regenerate lost periodontal tissue with new bone, periodontal ligament, and cementum [8]. Also, the guided bone regeneration (GBR) procedure has been performed for bone regeneration of peri-implant defects [9].

For successful periodontal regeneration by the GTR procedure, the role of a barrier membrane is very important [10]. Therefore, many scientific efforts have focused on the development of effective barrier membranes [11, 12]. Non-resorbable membranes have a superior capacity for cell occlusion and space maintenance [13]. However, these membranes have drawbacks, such as frequent membrane exposure and the necessity of a second surgery for membrane removal [14]. Therefore, resorbable membranes are widely used for guided tissue or bone regeneration. Resorbable membranes have been shown to be comparable to non-resorbable membranes with regard to probing depth reduction, clinical attachment gain, and percent of bone fill [15].

Collagen appears to be an ideal choice for resorbable membranes because of excellent biocompatibility and capacity to enhance the wound healing process [16]. In addition, collagen membranes have shown no adverse effect to surrounding tissues during the degradation process [17]. This is another advantage of collagen compared to synthetic materials, such as poly(lactide-co-glycolide) (PLGA), that induce foreign body reactions during degradation [18]. Nevertheless, the degradation of collagen membranes is too fast to maintain the structural integrity necessary for bone/tissue regeneration. To prolong the degradation time of collagen membranes, various cross-linking techniques have been developed. Many studies showed that the higher the degree of cross-linking, the slower the rate of degradation of the collagen membrane [19].

For cross-linking, chemicals such as formaldehyde and glutaraldehyde are added to collagen membranes. These chemicals could adversely influence surrounding tissues. In fact, the glutaraldehyde technique, the most widely used chemical cross-linking technique, was reported to leave a cytotoxic residue during the process [20].

The aim of this study is to evaluate the ability of a porous non-chemical cross-linking porcine-derived collagen nanofibrous membrane to enhance guided bone and associated tissue regeneration in one-wall intrabony defects in beagles.

MATERIALS AND METHODS

Animals

Two adult male beagle dogs with intact dentition and healthy periodontium were used as subjects. Animal selection, management, surgical protocol, and periodontal defect preparation followed routines approved by the Institute of Laboratory Animal Resources at Seoul National University. The animals were provided with a standard laboratory diet and water until the beginning of the study. The animals were provided with a soft diet throughout the study to reduce mechanical interference with healing during food intake. Oral prophylaxis was performed within the 2 weeks prior to the experimental surgeries.

Preparation of membranes

Ten percent collagen solution was made with 5 g collagen and 50 mL hexafluoroisopropanol. The membranes were prepared by electro-spinning the collagen solution and collecting sheets of nano-fibers, followed by cross-linking with heat treatment and the non-chemical method. The cross-linked collagen membrane was prefrozen in a deep freezer for 12 hours and freeze-dried for 24 hours. After freeze-drying, the collagen membrane was dried in the oven at 140℃ for 48 hours. The collagen membrane (Guidoss, NIBEC, Seoul, Korea) was then used in this study.

Surgical procedures

Food was withheld the night before surgery. General anesthesia was induced with 2% xylazine hydrochloride and ketamine hydrochloride. Routine dental infiltration anesthesia with 2% lidocaine with epinephrine (1:100,000) was used at the surgical sites. Under anesthesia, the second and third mandibular premolars and first molars were extracted bilaterally. The extraction sites were allowed to heal for 10 weeks.

After the 10-week healing interval, one-wall intrabony defects were prepared bilaterally on the mesial and distal side of the fourth mandibular premolars. Crestal incisions of 20 mm length were made on the mesial and distal side of the fourth premolars and connected with sulcular incisions made circumferentially. Vertical incisions were made at the end of the crestal incision, followed by periodontal flap reflections. After flap reflection, one-wall intrabony defects sized 4 × 5 mm (mesio-distal width and apico-coronal height, respectively) were created on the mesial and distal sides of the fourth premolars using round and fissure burs with sterile saline irrigation (Fig. 1A). Cementum was removed completely by root planing using Gracey curettes and chisels. Reference notches were made with a #1 round bur on the root surface at the base of the defect, and at the cementoenamel junction (CEJ) for histometric analysis.

Figure 1
Clinical photography representing the surgical procedure. (A) 4 (mesio-distal) × 5 (apico-coronal) mm one-wall intrabony defects were prepared at the mesial and distal portion of the fourth premolar. (B) One defect was not covered with membrane (control), and the other was covered with membrane (experimental). The membrane was stabilized with a fixation screw (arrowheads: border of collagen membrane). (C) Primary flap closure was achieved at all defect sites.

Click for larger image

Of the two defects of each fourth premolar, one was not covered with a membrane as a control and the other was covered with the collagen membrane (Guidoss, NIBEC, Seoul, Korea) as the experimental group (Fig. 1B).

Membranes were stabilized with fixation screws on each of the defects. After defect management, periosteal-releasing incisions were made to allow for tension-free flap apposition. The flaps were advanced, and sutured slightly coronal to the CEJ (Fig. 1C).

Post-surgical protocol

Post-surgical management of the animals involved intramuscular injection of cefazolin (20 mg/kg) with carprofen (4.4 mg/kg) daily for 3 days, a soft diet, and topical application of a 2% solution of chlorhexidine gluconate three times a week for 10 weeks. The sutures were removed 2 weeks after surgery.

Histologic processing and evaluation

The animals were sacrificed 10 weeks after surgery. All defects were dissected with the surrounding soft and hard tissues. The tissue blocks were fixed in 10% buffered formalin for 3-5 days, decalcified in 5% formic acid for 8-10 weeks, trimmed, dehydrated in an ethanol series, and embedded in the embedding media. Step serial sections were prepared along the mesio-distal plane and parallel with the long axis of the tooth, and stained with hematoxylin-eosin.

Histological and histometric analysis

Analysis was performed using a light microscope (BH-2, Olympus Optical, Osaka, Japan), a microscope digital camera system, and a PC-based image analysis system (Image-Pro Plus, Media Cybernetics, Silver Springs, MD, USA) by one investigator. The following parameters were measured and analyzed (Fig. 2):

Figure 2
Schematic drawing representing parameters for histometric analysis. CEJ: cemento-enamel junction, aJE: apical end of junctional epithelium, cNC: coronal extension of new cementum, cNB: coronal extension of new bone, DH: defect height, JE: junctional epithelium migration, NC: new cementum, NBh: new bone height, NBa: new bone area percentage.

Click for larger image

Defect height (DH): distance between the apical extension of the root planing and the CEJ.
Junctional epithelium migration (JE): the distance between the apical extension of the junctional epithelium and the CEJ.
New cementum (NC): distance between the apical extension of the root planing and the coronal extension of a continuous layer of new cementum or cementum-like deposit on the planed root.
New bone height (NBh): distance between the apical extension of the root planing and the coronal extension of alveolar bone formation along the planed root.
New bone area (NBa): NBa in the region of interest (ROI)/area of the ROI × 100 (%).

The ROI for NBa was measured by connecting 4 imaginary lines encompassing the defect base and the root surface to establish the region of interest with a shape of a 3 × 3 mm square (Fig. 2). The reason for this establishment was that the proposed standardized defects with the dimensions of 4 mm width × 5 mm height were difficult to create identically during surgery. Therefore, to eliminate any possible errors during evaluation, NBa was measured using an ROI of equal dimensions and position.

Radiographic analysis: micro-computed tomography (CT)

Following fixation, all samples were scanned by a high-resolution micro-CT (SkyScan 1172, SkyScan, Aartselaar, Belgium). Serial tomographic images were acquired transverse to the longitudinal axis of the tooth at 85 kV and 116 µA, collecting 1,200 projections per rotation at 316 ms integration time. Images were produced with a voxel size of 15 × 15 × 15 µm³.

The image data sets were reconstructed to three-dimensional views of the specimens and analyzed using software provided by the manufacturer (CT-Analyser, SkyScan, Aartselaar, Belgium). The percentile new bone volume (NBv) recorded represented the percentage of a volume of the newly formed bone in the region of interest. Various thresholds were applied to differentiate bone from graft particles, soft tissues, and bone marrow.

The region of interest for NBv was established with a cube shape of 4 mm dimensions encompassing the defect base and the root surface. The reason for the establishment of ROI for NBv was the same as the ROI for NBa.

Statistical analysis

The mean and standard deviations of each parameter were calculated for each treatment group using the values obtained from the subjects. Statistical analysis was performed using the software package (SPSS, SPSS Inc., Chicago, IL, USA). A paired Student's t-test was performed to compare data from the in vivo histomorphometric analysis. A P-value < 0.05 was considered statistically significant.

RESULTS

Clinical observations

Wound healing was uneventful at all surgical sites. There were no inflammatory signs following surgical procedures. Other postoperative complications such as wound dehiscence, membrane exposure, infection, and suppuration were not observed during the healing period.

Histologic analysis

In the control group, extensive bone resorption was observed. A crestal bone adjacent to the defect was resorbed to the level of the defect base. With bone resorption, soft tissue was collapsed into the defect. Bone regeneration was minimal. The regenerated bone was limited to the defect notch area. The junctional epithelium apically migrated to the notch on the CEJ. New cementum formation was minimal or not observed (Fig. 3A).

Figure 3
Histologic views of control and experimental group. (A) Histologic view of control group. Crestal bone was resorbed to the level of the defect base. With bone resorption, soft tissue was collapsed into the defect. The newly formed bone was limited to the defect notch area. New cementum formation was not observed. (B) Histologic view of the experimental group. Crestal bone was slightly resorbed. The newly formed bone was observed not only at the defect base but at the coronal area also. The quantity of newly formed bone was greater than in the control group. However, new cementum formation was not observed. The remaining collagen membrane could be observed (arrowheads).

Click for larger image

In the experimental group, a crestal bone adjacent to the defect had resorbed to some extent. However, the quantity of newly formed bone was greater than in the control group. Soft tissue collapse was observed into the defect but the extent was minimal compared to the control group. The apical migration of the junctional epithelium terminated within the CEJ notch area (Fig. 3B).

Histometric analysis

The results of histometric analysis are shown in Table 1. In the apical extension of the junctional epithelium, the experimental group showed a smaller mean value. This result might mean that the membrane prevented the junctional epithelium from undergoing apical migration. However, there was no statistically significant difference between the groups.

Table 1
Histometric analysis of periodontal regenerative capacity (mean ± SD).

Click for larger image

For new cementum formation, there was no statistically significant difference between groups. Also, large variations were observed within the same group.

The NBh of the experimental group was greater than the control group. The experimental group showed a significantly greater value of NBh compared with the control group (P = 0.003). Also, for the NBa, the experimental group showed a greater value than the control group, representing a statistically significant difference (P = 0.013).

Radiographic analysis: micro-CT

The NBv results are shown in Table 2. The experimental group showed a greater value compared to the control group. There was a statistically significant difference between groups. Radiographic images of both groups were similar to histologic results (Fig. 4).

Figure 4
Radiographic analysis using micro-CT. (A) Mesio-distal section of control group. Newly formed bone was minimal. The radiographic image was similar to the histologic view in Fig. 3A. The red arrow indicates the midpoint of the defect notch and the blue arrow 2 mm above the level of the red arrow. (B) Horizontal section at the level of the blue arrow in Fig. 4A. Newly formed bone was not observed. (C) Horizontal section at the level of the red arrow in Fig. 4A. The newly formed bone was minimal and observed only at the defect notch. (D) Mesio-distal section of experimental group. The newly formed bone was apparent and not limited to the defect base. Red and blue arrows indicate the same point with Fig. 4A. (E) Horizontal section at the level of the blue arrow in Fig. 4D. The newly formed bone was observed at a more coronal level compared to control group. (F) Horizontal section at the level of the red arrow in Fig. 4D. The newly formed bone occupied the whole area near the defect base. New bone formation was more pronounced than in the control group.

Click for larger image

Table 2
Radiographic analysis of periodontal regenerative capacity (mean ± SD, %).

Click for larger image

DISCUSSION

In the present study, one-wall intrabony defects were used to evaluate the effect of a porous non-chemical cross-linking porcine-derived collagen nanofibrous membrane on periodontal tissue regeneration. This defect model is unfavorable for bone regeneration since a positive correlation between the number of bone walls and wound-healing potential exists [21]. In addition, this defect model is a non-contained defect in which is difficult for resorbable membranes to maintain the space. Therefore, it was possible to strictly evaluate the effect of this membrane on periodontal tissue regeneration.

The most remarkable result observed in this study was the effect of this membrane on bone regeneration. For the three parameters used to evaluate bone regeneration, NBh, NBa, and NBv, the experimental group showed superior results compared to the control group, constituting statistically significant differences. These results imply that this collagen membrane enhanced bone regeneration in one-wall intrabony defects. It is noteworthy that these results were attained in an unfavorable defect model for bone regeneration. In previous studies, in non-contained defects like one-wall intrabony defects or supra-alveolar defects, the combined use of a barrier membrane and bone graft showed greater bone formation than only membrane use [13, 22, 23]. In their systematic review, Sculean et al. [24] concluded that in non-contained defects like supra-alveolar defects, a combination of a barrier membrane and graft material provided superior histologic bone repair results to barrier membranes or graft materials alone. Therefore, more bone regeneration is expected to occur if this collagen membrane is used with a bone graft in this defect model.

For a more accurate evaluation of bone regeneration, three parameters--NBh, NBa, NBv--were used in this study. Through these parameters, new bone formation was analyzed one- (length), two- (area), and three-dimensionally (volume).

NBv was analyzed with micro-CT. Micro-CT has been used extensively to characterize bone tissue and analyze the bone healing process [25, 26]. Even though histologic analysis is still considered the gold standard for evaluating bone regeneration in bony defects [27], many previous studies have shown a consistent pattern of bone formation in both micro-CT and histological images [28, 29]. In this study, images from the micro-CT were similar to histologic images, similar to the results of previous studies (Fig. 4). In this respect, new bone volume was measured with the micro-CT as a parameter for evaluating bone regeneration.

Unlike bone regeneration, the collagen membrane did not influence periodontal tissue regeneration in the present study. There was no statistically significant difference between the two groups in the apical migration of the junctional epithelium. This finding shows that barrier membranes do not affect the apical extension of the junctional epithelium. Previous studies showed similar results, observing that the apical extension of junctional epithelium was small regardless of the use of a barrier membrane [30, 31]. Song et al. [30] reported that there was no significant difference in the junctional epithelium migration between the control and PLGA membrane groups in surgically created one-wall defects in beagles.

New cementum formation was minimal in both groups. Although the experimental group showed a greater mean value compared to the control group, there was no statistically significant difference. Large variations were observed within the same group. On the other hand, in previous studies, cementum regeneration was apparently observed at the GTR site in histologic analysis [32-34]. Sculean et al. [33] reported that new alveolar bone and connective tissue attachment (new cementum with inserted collagen fibers) were regenerated in the intrabony defect after GTR using a resorbable membrane. Therefore, further investigation is necessary to confirm the influence of this membrane on periodontal tissue regeneration.

In summary, the present study confirmed the capacity of the porous non-chemical cross-linking porcine-derived collagen nanofibrous membrane for bone regeneration in a one-wall intrabony defect model. Through various parameters used to evaluate bone regeneration, it was shown that this membrane enhanced bone regeneration at the periodontal defect. On the other hand, the influence of this membrane on periodontal tissue regeneration could not be ascertained within the limitations of this study, and further investigations are necessary.

Notes

No potential conflict of interest relevant to this article was reported.

ACKNOWLEDGEMENTS

This study was supported by the Korea Science and Engineering Foundation, through the Intellectual Biointerface Engineering Center at Seoul National University. The authors thank, Jue-Yeon Lee, Sang-Cheol Lee, and Jung-Bin Kim, who were from Nano-Intelligent Bioengineering Corporation, for preparing the materials.

References

1. Ramfjord SP, Knowles JW, Nissle RR, Burgett FG, Shick RA. Results following three modalities of periodontal therapy. J Periodontol 1975;46:522–526.
  PubMed
  
  CrossRef
1. Kaldahl WB, Kalkwarf KL, Patil KD, Molvar MP, Dyer JK. Long-term evaluation of periodontal therapy: I. Response to 4 therapeutic modalities. J Periodontol 1996;67:93–102.
  PubMed
  
  CrossRef
1. Becker W, Becker BE, Caffesse R, Kerry G, Ochsenbein C, Morrison E, et al. A longitudinal study comparing scaling, osseous surgery, and modified Widman procedures: results after 5 years. J Periodontol 2001;72:1675–1684.
  PubMed
  
  CrossRef
1. Caton J, Nyman S. Histometric evaluation of periodontal surgery. I. The modified Widman flap procedure. J Clin Periodontol 1980;7:212–223.
  PubMed
  
  CrossRef
1. Caton J, Nyman S, Zander H. Histometric evaluation of periodontal surgery. II. Connective tissue attachment levels after four regenerative procedures. J Clin Periodontol 1980;7:224–231.
  PubMed
  
  CrossRef
1. Bowers GM, Chadroff B, Carnevale R, Mellonig J, Corio R, Emerson J, et al. Histologic evaluation of new attachment apparatus formation in humans. Part I. J Periodontol 1989;60:664–674.
  PubMed
  
  CrossRef
1. Gottlow J, Nyman S, Karring T, Lindhe J. New attachment formation as the result of controlled tissue regeneration. J Clin Periodontol 1984;11:494–503.
  PubMed
  
  CrossRef
1. Garrett S. Periodontal regeneration around natural teeth. Ann Periodontol 1996;1:621–666.
  PubMed
  
  CrossRef
1. Buser D, Dula K, Belser U, Hirt HP, Berthold H. Localized ridge augmentation using guided bone regeneration. 1. Surgical procedure in the maxilla. Int J Periodontics Restorative Dent 1993;13:29–45.
  PubMed
1. Dahlin C, Sennerby L, Lekholm U, Linde A, Nyman S. Generation of new bone around titanium implants using a membrane technique: an experimental study in rabbits. Int J Oral Maxillofac Implants 1989;4:19–25.
  PubMed
1. Simion M, Scarano A, Gionso L, Piattelli A. Guided bone regeneration using resorbable and nonresorbable membranes: a comparative histologic study in humans. Int J Oral Maxillofac Implants 1996;11:735–742.
  PubMed
1. Schliephake H, Dard M, Planck H, Hierlemann H, Jakob A. Guided bone regeneration around endosseous implants using a resorbable membrane vs a PTFE membrane. Clin Oral Implants Res 2000;11:230–241.
  PubMed
  
  CrossRef
1. Polimeni G, Koo KT, Qahash M, Xiropaidis AV, Albandar JM, Wikesjo UM. Prognostic factors for alveolar regeneration: effect of a space-providing biomaterial on guided tissue regeneration. J Clin Periodontol 2004;31:725–729.
  PubMed
  
  CrossRef
1. Ling LJ, Hung SL, Lee CF, Chen YT, Wu KM. The influence of membrane exposure on the outcomes of guided tissue regeneration: clinical and microbiological aspects. J Periodontal Res 2003;38:57–63.
  PubMed
  
  CrossRef
1. Parrish LC, Miyamoto T, Fong N, Mattson JS, Cerutis DR. Non-bioabsorbable vs. bioabsorbable membrane: assessment of their clinical efficacy in guided tissue regeneration technique. A systematic review. J Oral Sci 2009;51:383–400.
  PubMed
  
  CrossRef
1. Locci P, Calvitti M, Belcastro S, Pugliese M, Guerra M, Marinucci L, et al. Phenotype expression of gingival fibroblasts cultured on membranes used in guided tissue regeneration. J Periodontol 1997;68:857–863.
  PubMed
  
  CrossRef
1. Quteish D, Singrao S, Dolby AE. Light and electron microscopic evaluation of biocompatibility, resorption and penetration characteristics of human collagen graft material. J Clin Periodontol 1991;18:305–311.
  PubMed
  
  CrossRef
1. Polimeni G, Koo KT, Pringle GA, Agelan A, Safadi FF, Wikesjo UM. Histopathological observations of a polylactic acid-based device intended for guided bone/tissue regeneration. Clin Implant Dent Relat Res 2008;10:99–105.
  PubMed
  
  CrossRef
1. Minabe M, Kodama T, Kogou T, Tamura T, Hori T, Watanabe Y, et al. Different cross-linked types of collagen implanted in rat palatal gingiva. J Periodontol 1989;60:35–43.
  PubMed
  
  CrossRef
1. Speer DP, Chvapil M, Eskelson CD, Ulreich J. Biological effects of residual glutaraldehyde in glutaraldehyde-tanned collagen biomaterials. J Biomed Mater Res 1980;14:753–764.
  PubMed
  
  CrossRef
1. Kim CS, Choi SH, Chai JK, Cho KS, Moon IS, Wikesjo UM, et al. Periodontal repair in surgically created intrabony defects in dogs: influence of the number of bone walls on healing response. J Periodontol 2004;75:229–235.
  PubMed
  
  CrossRef
1. Wikesjo UM, Lim WH, Razi SS, Sigurdsson TJ, Lee MB, Tatakis DN, et al. Periodontal repair in dogs: a bioabsorbable calcium carbonate coral implant enhances space provision for alveolar bone regeneration in conjunction with guided tissue regeneration. J Periodontol 2003;74:957–964.
  PubMed
  
  CrossRef
1. Blumenthal NM, Alves ME, Al-Huwais S, Hofbauer AM, Koperski RD. Defect-determined regenerative options for treating periodontal intrabony defects in baboons. J Periodontol 2003;74:10–24.
  PubMed
  
  CrossRef
1. Sculean A, Nikolidakis D, Schwarz F. Regeneration of periodontal tissues: combinations of barrier membranes and grafting materials - biological foundation and preclinical evidence: a systematic review. J Clin Periodontol 2008;35:106–116.
  PubMed
  
  CrossRef
1. Muller R, Hahn M, Vogel M, Delling G, Ruegsegger P. Morphometric analysis of noninvasively assessed bone biopsies: comparison of high-resolution computed tomography and histologic sections. Bone 1996;18:215–220.
  PubMed
  
  CrossRef
1. Butz F, Ogawa T, Chang TL, Nishimura I. Three-dimensional bone-implant integration profiling using micro-computed tomography. Int J Oral Maxillofac Implants 2006;21:687–695.
  PubMed
1. Cowan CM, Aghaloo T, Chou YF, Walder B, Zhang X, Soo C, et al. MicroCT evaluation of three-dimensional mineralization in response to BMP-2 doses in vitro and in critical sized rat calvarial defects. Tissue Eng 2007;13:501–512.
  PubMed
  
  CrossRef
1. Marechal M, Luyten F, Nijs J, Postnov A, Schepers E, van Steenberghe D. Histomorphometry and micro-computed tomography of bone augmentation under a titanium membrane. Clin Oral Implants Res 2005;16:708–714.
  PubMed
  
  CrossRef
1. Kochi G, Sato S, Ebihara H, Hirano J, Arai Y, Ito K. A comparative study of microfocus CT and histomorphometry in the evaluation of bone augmentation in rat calvarium. J Oral Sci 2010;52:203–211.
  PubMed
  
  CrossRef
1. Song WS, Kim CS, Choi SH, Jhon GJ, Kim HY, Cho KS, et al. The effects of a bioabsorbable barrier membrane containing safflower seed extracts on periodontal healing of 1-wall intrabony defects in beagle dogs. J Periodontol 2005;76:22–33.
  PubMed
  
  CrossRef
1. Yeo YJ, Jeon DW, Kim CS, Choi SH, Cho KS, Lee YK, et al. Effects of chitosan nonwoven membrane on periodontal healing of surgically created one-wall intrabony defects in beagle dogs. J Biomed Mater Res B Appl Biomater 2005;72:86–93.
  PubMed
  
  CrossRef
1. Stoller NH, Johnson LR, Garrett S. Periodontal regeneration of a class II furcation defect utilizing a bioabsorbable barrier in a human. A case study with histology. J Periodontol 2001;72:238–242.
  PubMed
  
  CrossRef
1. Sculean A, Donos N, Chiantella GC, Windisch P, Reich E, Brecx M. GTR with bioresorbable membranes in the treatment of intrabony defects: a clinical and histologic study. Int J Periodontics Restorative Dent 1999;19:501–509.
  PubMed
1. Sculean A, Donos N, Windisch P, Brecx M, Gera I, Reich E, et al. Healing of human intrabony defects following treatment with enamel matrix proteins or guided tissue regeneration. J Periodontal Res 1999;34:310–322.
  PubMed
  
  CrossRef