To prevent infections after orthopedic surgery, intravenous antibiotics are administered perioperatively. Cefazolin is widely used as the prophylactic antibiotic of choice. Systemic antibiotic therapy may however be less effective in longstanding surgery where bone allografts are used. Bone chips have been shown to be an effective carrier for certain types of antibiotics. Bone allografts impregnated with antibiotics may therefore provide the necessary local antibiotic levels for prophylaxis. To be efficient, a prolonged release from these bonechips is required. In contrast to vancomycin, for which prolonged release has clearly been proven effective from Osteomycin®, a commercially available impregnated bone allograft, no prolonged release bone chip preparations have been described so far for cefazolin. We developed a protocol to bind cefazolin in the porous structure of bone chips by means of a hydrogel composed of proteins naturally present in the human body.

Three types of bone chips were evaluated: fresh frozen, decellularized frozen and decellularized lyophilized. Bone chips were incubated with 20 mg/ml cefazolin or treated with liquid hydrogel containing either 1 mg/ml fibrin or 1 mg/ml collagen and 20 mg/ml cefazolin. The cefazolin hydrogel was distributed in the porous structure by short vacuum treatment. Bone chips with cefazolin but without hydrogel were either incubated for 20 min- 4h or also treated with vacuum. Cefazolin elution of bone chips was carried out in fetal bovine serum and analyzed by Ultra Performance Liquid Chromatography – Diode Array Detection.

Soaking of bone chips without hydrogel resulted in a quick release of cefazolin, which was limited to 4 hours. When vacuum was applied elution of >1 µg/ml cefazolin was measured for up to 36 hours. Combination with collagen hydrogel resulted in a higher cefazolin concentration released at 24 hours (3.9 vs 0.3 µg/ml), but not in a prolonged release. However, combination of decellularized frozen bone chips with fibrin hydrogel resulted in an initial release of 533 µg/ml followed by a gradual decline reaching the minimal inhibitory concentration for S. aureus at 72 hours (1.7 µg/ml), while not measurable anymore after 92 hours.

Processed bone chips with hydrogel-cefazolin showed a markedly prolonged cefazolin release. When combined with a fibrin hydrogel, high initial peak levels of cefazolin were obtained, followed by a decreasing release over the following three days. This elution profile is desirable, since high initial levels are important to maximize anti-bacterial action whereas low levels of antibiotic for a limited time may stimulate osteogenesis. It is important that antibiotic release is ending after a few days as prolonged low levels of antibiotics are not clinically helpful and may lead to antibiotic resistance. Further preclinical studies are warranted to show effectiveness of hydrogel-cefazolin impregnated bone chips.

Aim

To prevent infections after orthopaedic surgery, intravenous antibiotics are administered perioperatively. Cefazolin is widely used as the prophylactic antibiotic of choice. Systemic antibiotic therapy may however be less effective in longstanding surgery where bone allografts are used. Bone chips have been shown to be an effective carrier for certain types of antibiotics and may provide the necessary local antibiotic levels for prophylaxis. To be efficient a prolonged release is required. In contrast to vancomycin with proven efficient prolonged release from Osteomycin, this has not been described for cefazolin. We developed a protocol to bind cefazolin to bone chips by means of a hydrogel composed of proteins naturally present in the human body.

Vancomycin -impregnated bonechips from a human morselized femoral head allograft (BCs) are used in orthopaedic surgery to treat infections. Literature suggests that bonechips can be efficient vancomycin carriers, but due to the diversity in the type of bonechips, of impregnation and of method used to evaluate AB release, there are no uniform guidelines. We performed an in vitro study to examine the release of vancomycin from solution-impregnated deepfrozen processed bonechips. Quantification was performed using a fully validated chromatographic method. Results were compared with the elution-profile from Osteomycin®, a commercially available lyophilised processed bonegraft.

Different vancomycine impregnation-concentrations and impregnation-durations of frozen processed bonechips were investigated. After impregnation, bonechips were rinsed with saline in order to determine only the absorbed vancomycin. Elution was performed in newborn calf serum at 37°C. Eluted vancomycin concentrations were determined using Ultra Performance Liquid Chromatography – Diode Array Detection (UPLC-DAD). In addition an elution study was performed on the commercially available Osteomycin®, bone chips containing vancomycine.

Using processed frozen bonechips, an impregnation-concentration of minimum 100 mg/mL during 10 minutes delivers the desired local concentration (therapeutic window 25 – 1000 mg/L) for 3 days. Longer impregnation time at this concentration had no effect. Osteomycin®: delivers the desired local concentration for 8 days in our experimental setting.

Literature suggests that freshfrozen BCs can be used as carrier for vancomycin through solution-impregnation [1,3]. There is however much less information on the carrier-capacities of frozen processed bonechips, a type used in our hospital. Our impregnation-protocol was based on that of Mathyssen et al., but with direct quantification of elution concentrations. Impregnation with vancomycine 100 mg/mL during 10 minutes results in a release above the desired concentration for 3 days, which seems too short when treating bone-infections. Osteomycin®, shows a substantially longer elution [2].

Vancomycin-solution impregnation of frozen processed bonechips may not be sufficient to obtain the desired release-characteristics for the treatment of bone-infections.