Delayed Methicillin-Resistant Staphylococcus aureus Infection on a Mandibular Angle Fracture with Absorbable Plates

Article information

Arch Plast Surg. 2015;42(2):252-254
Publication date (electronic) : 2015 March 16
doi : https://doi.org/10.5999/aps.2015.42.2.252
Department of Plastic Surgery, Konkuk University Hospital, Konkuk University School of Medicine, Chungju, Korea.
Correspondence: Dongin Jo. Department of Plastic Surgery, Konkuk University Hospital, Konkuk University School of Medicine, 82 Gugwon-daero, Chungju 380-704, Korea. Tel: +82-10-8742-0831, Fax: +82-43-840-8962, dijo@medigate.net
Received 2014 May 13; Revised 2014 July 12; Accepted 2014 July 12.

Absorbable fixation is used worldwide for bone fixation. Because it is absorbed into the body by a hydrolysis process, removal is unnecessary. Inflammation, swelling, and acute infection can occur [1], but with less frequency in delayed type infections [2]. The authors report on a case of infection that was delayed for one year in a patient who underwent mandibular fracture fixation using absorbable plates. A 17-year-old male arrived as an outpatient with a chief complaint of a left mandibular mass. His past history included seizure and mental retardation due to hydrocephalus (diagnosed at six months after birth) and a medication history of asthma. One year ago, he underwent a procedure of open reduction using absorbable plates on his mandible. Five weeks after fixation, wound dehiscence and purulent discharge was noted and revision was performed. Methicillin-resistant Staphylococcus aureus (MRSA) was cultured from discharge of the wound. Vancomycin 500 mg was administered in IV form for seven days until no microbium was cultured from the wound. After revision, the wound showed improvement.

When the patient visited our outpatient department, a firm round mass was palpated at the left mandibular margin (Fig. 1). The nature of the mass was hard and fixed with adjacent tissues. Redness, heating sense, and swelling were observed around the mass. Communication was difficult due to the patient's status of hydrocephalus; however, avoidance of palpation indicated possible tenderness near the mass. The patient's initial white blood cell, C-reactive protein, erythrocyte sedimentation rate lab, and a plain radiograph showed no specific finding. Ultrasonography showed a small abscess in the left mandibular angle. Computed tomography angiography was performed for further evaluation and combined osteomyelitis and an abscess with osteophytes surrounding the mandible were suspected. Despite treatment with medication, the patient showed no improvement. Therefore, our department took the next step, resection of the osteomyelitic lesion with minor abscesses. Under general anesthesia, the patient was placed in a supine position. His previous operation site allowed an approach to the mandible, where the lesion was located. Partial division of the masseter muscle also allowed an approach to the mandible. The mass was composed of infected soft tissue and granulation tissue (Fig. 2). Some serous discharge and degradation parts of the implant were observed on the cortical bone. Swab culture and tissue biopsy was performed. There was no sign of osteomyelitis and cortical bone integrity was observed, therefore, bone resection was unnecessary. Finally, irrigation was performed followed by drain insertion and layer by layer suture. The drain was removed on postoperative day (POD) #2, leaving no sign of skin complication. On POD #5, vancomycin was applied due to the positive MRSA result from wound culture. Tissue biopsy showed some macrophages containing granulation tissue (Fig. 3). The patient had no abnormal lab results during the admission period. Two weeks after surgery, the patient had made a full recovery, and has remained in good health.

Fig. 1

Preoperative view of the mass.

Fig. 2

(A) Intraoperative view of the operation field. (B) Remnant of the absorbable plate and screw. (C) Follow-up photograph at 15 days postoperatively.

Fig. 3

Microscopic finding of the mass. The specimen shows focal loose granulation tissue with some macrophages. The remaining portion shows fibrosis (H&E, ×40).

Biodegradable plate and screw are often used in craniofacial skeleton surgery. Polyglycolide, developed by Dexon in 1970, is the first absorbable fixation to be synthesized, followed by PDS, vicryl. Absorbable fixation is currently used successfully [3], with materials based on lactic, glycolic acid. Superior material is helpful in maintaining strength of surrounding tissues, thereby preventing inflammation, toxic effect, and carcinogenic response until the wound is completely healed. Degradation of the absorbable material is influenced by many factors. For example, size of implant, type of material, characteristics of insertion location of materials, vascularity of the tissue surrounding implantation, age, general health, etc. There are two degradation phases, phase I (hydrolysis) and phase II. Phase I is an active degradation phase as contact with water is initiated. Phase II involves conversion of debridement into CO2, H2O by macrophages, and initiation of the tricarboxylic acid cycle metabolism. Balance of hydrolysis and metabolism is important, due to the fact that if the amount of hydrolysis product exceeds the amount of metabolism, inflammation will occur. In this case, it is thought that infection resulted from a remnant of previous wound tissue and absorbable fixators. Complete absorption of absorbable fixators could take more than 12 months [4]. During that period, infection at absorbable fixators is possible. A degraded absorbable fixator acts like a culture medium of microbium.

According to research reported by Laughlin et al. [5], neither infection rate nor revision rate was higher for patients with a mandible fracture who underwent an operation using an absorbable plate, compared to metal fixation. Out of 50 patients with a mandible fracture, 6% had infection, 4% with hardware removal. In the control group described in the review article, out of 617 patients, 3.9% had nonunion/fibrous union, 13% with infection, and 18.9% had hardware removal. Accordingly, regular follow up is essential for use of absorbable fixators in patients. Infection is the most important and considerable complication in mandibular fracture fixation using the absorbable fixator method. Normally, where mass growth is initiated in an acute postoperative period, primary infection is most likely considerable. However, in the case described above, where the mass showed late growth, circumstantial evaluation of the mass itself is important. Accurate knowledge of types of complication will eventually be helpful in proper management of operation site mass genesis.

Notes

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

References

1. Choi HJ, Kim W, Youn S, et al. Management of delayed infection after insertion of bioresorbable plates at the infraorbital rim. J Craniofac Surg 2012;23:524–525. 22421862.
2. Lee JH, Chang JW, Choi MS, et al. Delayed infection after a zygoma fracture fixation with absorbable plates. J Craniofac Surg 2010;21:2018–2019. 21119490.
3. Tripathi N, Goyal M, Mishra B, et al. Zygomatic complex fracture: a comparative evaluation of stability using titanium and bio-resorbable plates as one point fixation. Natl J Maxillofac Surg 2013;4:181–187. 24665173.
4. Losken HW, van Aalst JA, Mooney MP, et al. Biodegradation of Inion fast-absorbing biodegradable plates and screws. J Craniofac Surg 2008;19:748–756. 18520394.
5. Laughlin RM, Block MS, Wilk R, et al. Resorbable plates for the fixation of mandibular fractures: a prospective study. J Oral Maxillofac Surg 2007;65:89–96. 17174770.

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Fig. 1

Preoperative view of the mass.

Fig. 2

(A) Intraoperative view of the operation field. (B) Remnant of the absorbable plate and screw. (C) Follow-up photograph at 15 days postoperatively.

Fig. 3

Microscopic finding of the mass. The specimen shows focal loose granulation tissue with some macrophages. The remaining portion shows fibrosis (H&E, ×40).