Comparative Study of Tissue Response to Polyglecaprone 25, Polyglactin 910 and Polytetrafluorethylene Suture Materials in Rats

 

 

Hugo NARY FILHO1
Mariza Akemi MATSUMOTO1
Aline Carvalho BATISTA1
Luís César LOPES1
Fernanda Costa Grizzo de SAMPAIO GÓES2
Alberto CONSOLARO2


1Department of Oral Surgery, School of Dentistry, Sacred Heart University (USC), Bauru, SP, Brazil
2Department of Stomatology, Discipline of Oral Pathology, Faculty of Dentistry at Bauru, USP, Bauru, SP, Brazil
 

Correspondence: Dr. Hugo Nary Filho, Rua Rio Branco 19-79, 17040-480 Bauru, SP, Brasil. E-mail: iocp@uol.com.br


Braz Dent J (2002) 13(2): 86-91   ISSN 0103-6440

INTRODUCTION | MATERIAL AND METHODS | RESULTS | DISCUSSION | RESUMO| REFERENCES


The authors evaluated the biocompatibility of three suture materials, polyglecaprone 25, polyglactin 910 and polytetrafluorethylene, implanted into subcutaneous tissue in the dorsal region of 20 Wistar albinus rats. After periods of 2, 7, 14 and 21 days, the rats were sacrificed and the specimens were processed for routine histotechnical analysis and stained with hematoxylin and eosin. The rate of fibrosis, angioblastic and fibroblastic proliferation, and also the intensity of inflammation were observed with the optic microscope. The results showed that polyglecaprone 25 suture material induced a mild inflammatory reaction, followed by polyglactin 910 and polytetrafluorethylene, respectively. Such biological behavior must be considered during the selection of the suture material to be used in oral surgery.

Key Words: polyglecaprone 25, polyglactin 910, polytetrafluorethylene, suture material.


INTRODUCTION

Sutures play an important role in wound healing after surgical interventions and thus the selection of suture material, especially in oral procedures, must be made carefully. This location differs from other body sites due to the constant presence of saliva, specific microbiota, high vascularization, as well as its functions related to speech, mastication, and swallowing (1). The search for more appropriate suture material has resulted in a variety of natural and synthetic, absorbable and nonabsorbable sutures available commercially. These features influence biological reactions to the suture, permitting a great diversity of clinical applications.

Several clinical and experimental studies have tried to establish the ideal suture (2-7) taking into account factors such as their intrinsic biological com patibility, physical features, permeability to oral fluids and clinical applicability.

Recently available on the market, polyglecaprone 25 monofilament suture material, a copolymer of glycolide and e-copralactone, absorbable by hydrolysis in a period of 91 to 119 days, presents excellent strength, reduced memory and large malleability. It is a synthetic suture, and because of its favorable characteristics can be used not only deeply in tissues, but also in superficial tissues of oral mucosa (6). However, despite these commercial considerations, a comparative study between this specific suture and those commonly used in dental practice is needed.

The aim of this study was to observe the biological reactions of polyglecaprone 25 suture implanted in subcutaneous tissue of rats compared to polyglactin 910 and polytetrafluorethylene sutures with well known results and clinical applicability (6,8,9).


MATERIAL AND METHODS

Twenty male Wistar albinus rats, weighing about 250 g and fed a solid diet and water ad libitum, were divided into 4 groups of 5 rats each. The animals were anesthetized with sulfuric ether, and after shaving and scrubbing the dorsal area with an antiseptic solution, a 4-cm longitudinal incision was made along the medial line in the dorsal subcutis.

Each animal received three sutures: polyglecaprone 25 (Monocryl, Ethicon, São José dos Campos, SP, Brazil), poyglactyn 910 (Vycril, Ethicon, São José dos Campos, SP, Brazil) and polytetrafluorethylene (e-PTFE, Gore-Tex, Flagstaff, AZ, USA) with a 1.5-cm interval between them. The sutures had the same thickness (4-0) and needle (semicircular, nontraumatic with triangle section). After 48 h, 7, 14 and 21 days, the animals were sacrificed and the sutures and the subcutaneous tissue were removed from the dorsal area. The specimens underwent routine histotechnical processing and were stained with hematoxylin and eosin for histological analysis.

Inflammation, rate of fibroblastic and angioblastic proliferation, and the presence of fibrous tissue surrounding the sutures were observed in each group and period, and scored according to their presence and intensity: 0 = absent; 1 = mild; 2 = moderate; 3 = severe.

For statistical analysis, median and semi-amplitude were calculated from the scores, and the Friedman test was applied.


RESULTS

Polyglecaprone 25

Microscopically, this suture was a homogeneous and bright material. Forty-eight hours after its implantation, focal neutrophilic inflammatory infiltrate was noted surrounding the suture. Areas of connective tissue alternated with areas of granulation tissue rich in ovoid and spindle cells (Figure 1a). On the seventh day, next to the suture, moderate mononuclear infiltrate was observed, with eventual neutrophils, although an initial fibroblastic and angioblastic proliferation could be seen (Figure 1b). The organization of the connective tissue was observed after 14 days, with collagen fibers and fibroblasts, and abundant capillaries. A few foreign body multinucleated giant cells were seen in this period (Figure 1c). On the 21st day, organized connective tissue surrounding the suture was noted (Figure 1d).

Polyglactin 910

After 48 h of suture implantation, optic microscopic analysis showed the presence of neutrophilic infiltrate ranging from moderate to intense surrounding the suture. These leucocytes could also be seen among the filaments of the suture. Disorganized connective tissue was seen, and no evidence of fibroblastic or angioblastic proliferation was noted (Figure 2a). On the 7th day, a slight organization of the connective tissue with angioblastic and fibroblastic proliferation was noted, as well as a moderate number of mononuclear leucocytes (Figure 2b). Foreign body giant cells were seen associated to the suture filaments after 14 and 21 days. Connective tissue was present surrounding the suture at 21 days (Figures 2c,d).

Polytetrafluorethylene

After 48 hours, extensive neutrophilic inflammatory infiltrate was seen close to the polytetrafluorethylene suture, irregular and brown in color (Figure 3a). The same infiltrate was still present after 7 and 21 days (Figures 3b,c); however, in distant areas, a vascularized and cellular granulation tissue could be seen, becoming an organized connective tissue in the last period. Foreign body multinucleated giant cells were also present at 21 days (Figure 3d).

Statistical Analysis

Forty-eight hours after suture implantation, no statistically significant difference was noted between polyglactin 910 and polytetrafluorethylene sutures in terms of intensity of neutrofilic inflammatory infiltrate. However, polyglecaprone 25 showed mild acute inflammatory reaction in this period that was statistically different from polytetrafluorethylene. During the following periods, statistically significant differences were observed between polytetrafluorethylene sutures and the others, with polytetrafluorethylene showing a more aggressive behavior to the subcutaneous tissue, with persistence of neutrophils until the last period of this study.

Mononuclear leukocyte infiltrate in the polyglecaprone 25 group was significantly less than that of the polytetrafluorethylene group only at 48 hours.

Differences related to fibroblastic and angioblastic proliferation were not regularly noted, with tissues surrounding the suture materials showing similarity in relation to the presence of angioblastic or fibroblastic cells.

Fibrosis observed around the sutures was statistically different between polytetrafluorethylene and the others, confirming the lack of collagen fiber organization around polytetrafluorethylene sutures up to the last day of the experiment with granulation tissue persisting. Statistical results can be better visualized in Table 1.


DISCUSSION

Sutures used in oral surgery behave differently from other parts of the body due to the quality of the tissues involved, presence of saliva, and specific microbiota. They represent a pathway communicating the internal and external regions of the tissues, influencing the quality of wound healing (1).

Searching for ideal suture materials implies not only biological compatibility, but also clinical behavior. They must present good resistance to traction, dimensional stability, lack of memory, good knot security, and enough flexibility not to damage oral mucosa. At the same time, they must avoid or limit bacterial adhesion and proliferation to those parts exposed to oral fluids, avoiding contamination inside the wound (2,10). A good suture material must show a brief exudative phase, not interferring with cellular proliferation or connective tissue organization.

Among the available suture materials, polyglactin 910 is one of the favorites in dental practice. Despite being braded, it is resistant to traction and easily manipulated. Clinical observations also show an excellent behavior, not permiting the adhesion of plaque, nor intense inflammatory reactions around it. Thus, this suture is often selected for oral surgeries, even when its removal is not intented, or for deep sutures. It was used for comparison in the analysis of polyglecaprone 25 suture, showing a good biological reaction, inducing moderate acute inflammatory response in early periods and early fibroblastic and angioblastic proliferation. It also permitted the organization of the fibrous connective tissue around itself at late periods, showing similar behavior as reported by Pavan et al. (4). Polyglecaprone 25 showed biological behavior similar to polyglactin 910. In the first period, 48 h, it was possible to observe a better biocompatibility with a less intense inflammatory reaction, organization of the connective tissue and a few areas of degenerated tissue.

Intense reactions during the initial periods are common features of the materials used in this study. In the first days after the surgery, the influence of trauma has to be considered, favoring a more intense tissue reaction. However, the better behavior of polyglecaprone 25 can be related to its chemical composition, 25% e-copralactone and 75% glycolid, and also to its monofilament characteristic. Physical configuration of the sutures is an important factor, despite the use of deep sutures in the present study, seen by the more agressive reactions promoted by braded suture (2,10). When it is used in oral mucosa, the possibility of bacterial adhesion to its filaments exists (3).

Polytetrafluorethylene suture is a polymer of carbon chain with fluoride atoms surrounding it, and it has been largely used in orthopedic and vascular surgeries. In oral surgeries, its use was proposed due to the procedure using membranes made from the same material (5). However, in the present study, it clearly presented the worst biological behavior in comparison to the other materials. From the first periods, it showed more aggressive inflammatory reaction, which persisted until the end of the experiment. Neutrophilic infiltrate present in the last period indicates an irritating characteristic of the suture, confirmed by the values of fibroblastic and angioblastic proliferation in comparison to the other sutures. These results differ from those found by Checchi et al. (9) who recommended this suture due to its favorable biological response. The similarity of the physical properties between polytetrafluorethylene and polyglecaprone 25 sutures, both are monofilaments, leads to the conclusion that the biological behavior of the former is due to its chemical composition.

Sutures in oral surgeries are often removed after a period of 7 to 10 days, when the differences among the materials are not as significant. However, under some circumstances, such as dealing with children or non-collaborative patients, sutures are not removed at all. In an attempt to offer a more comfortable post-operative time, especially for these patients, new suture materials are being produced, giving special attention to absorbable sutures, justifying the necessity of specific studies on their use in dentistry (6,7,12,13).

In this comparative study, polyglecaprone 25 suture material produced the best biological response. In addition to its chemical and physical properties, its indication in oral surgery procedures is recommended.


RESUMO

Nary Filho H, Matsumoto MA, Batista AC, Lopes LC, de Sampaio Góes FCG, Consolaro A. Estudo comparativo da resposta tecidual aos fios de sutura poliglecaprone 25, poliglactina 910 e politetrafluoretileno em ratos. Braz Dent J 2002;13(2):86-91.

Os autores avaliaram a resposta tecidual, em região subcutânea de ratos, frente a fios de sutura: poliglecaprone 25, poliglactina 910 e politetrafluoretileno. Para tanto foram utilizados 20 ratos Wistar albinus, onde praticou-se três pontos de sutura em planos profundos na região dorsal, com os diferentes materiais em estudo. Após períodos de 2, 7, 14 e 21 dias, grupos de cinco animais foram sacrificados para obtenção de espécimes que foram processados e corados pela hematoxilina e eosina. Na análise microscópica adotou-se como parâmetros o grau de fibrosamento, o índice de proliferação angioblástica, fibroblástica e a severidade do infiltrado inflamatório presente. Através desta análise pôde-se constatar que o fio de poliglecaprone 25 induziu reação inflamatória menos intensa, seguido pelos fios de poliglactina 910 e politetrafluoretileno, respectivamente. Tais resultados de comportamento biológico devem ser considerados quando da escolha do fio de sutura a ser empregado em cirurgias bucais.

Unitermos: poliglecaprone 25, poliglactina 910, politetrafluoretileno, fio de sutura.


REFERENCES

1. Certosimo FJ, Nicoli BK, Nelson RR, Wolfgang M. Wound healing and repair: a review of the art and science. Gen Dent 1998,46:362-369.

2. Lilly GE. Reaction of oral tissues to suture materials. Part III. Oral Surg 1969;26:432-437.

3. Lilly GE. Reaction of oral tissues to suture materials. Part IV. Oral Surg 1972;33:152-57.

4. Pavan A, Bosio M, Longo T. A comparative study of poly (glicolic acid) and catgut as suture materials. Histomorphology and mechanical properties. J Biomed Mater Res 1979;13:477-496.

5. La Scala G, Lleo MM. Suture in odontoiatria. Fili tradizionali e in PTFE. Dental Cadmos 1990;14:54-59.

6. Beswada RS, Jamiolkowski DD, Lee IY, Agarwal V, Persivale J, Trenka-Benthin S, Erneta M, Suryadevara J, Yang A, Liu S. Monocrylâ suture, a new ultra-pliable absobable monofilament suture. Biomaterials 1995;16:1141-1148.

7. Shaw RJ, Negus TW, Mellor TK. A prospective clinical evaluation of the longevity of resorbable sutures in oral mucosa. Br J Oral Maxillofac Surg 1996;34:252-254.

8. Okamoto T, Gabrielli MFR, Gabrielli MAC. Influence of different types of non-resorbable suture material on the healing of extraction wounds. J Nihon Univ Sch Dent 1990;32:104-115.

9. Checchi L, Franchi M, Zucchini C, Biagini G, Armandi M. Fili sintetici da sutura chirurgica. Analisi istologica in vivo. Dental Cadmos 1996;4:42-47.

10. Lilly GE, Armstrong JH, Salem JE, Cutcher JL. Reaction of oral tissues to suture materials. Part II. Oral Surg 1968;26:592-599.

11. Oliveira JAGP. Reação tecidual aos fios de sutura de algodão e de seda, estudo comparativo em ratos. Rev Fac Odont Rib Preto 1985;22:61-68.

12. Nary Filho H, Okamoto T, Padovan LEM. Estudo comparativo da resposta tecidual frente a fios de sutura de catgut e poliglecaprone 25 em subcutâneo de ratos. Salusvita 1996;15:127-142.

13. McCaul LK, Bagg J, Jenkins WMM. Rate of loss of irradiated polyglactin 910 (Vicryl Rapide) from the mouth: a prospective study. Br J Oral Maxillofac Surg 2000;38:328-330.

 


Accepted November 22, 2001


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