Combination therapy with vancomycin-loaded calcium sulfate and vancomycin-loaded PMMA in the treatment of chronic osteomyelitis

Chronic post-traumatic and postoperative osteomyelitis is a devastating complication of Orthopaedic trauma and reconstructive Orthopaedics, and is one kind of osteomyelitis with increasing number [1]. It is specially difficult to treat because of its refractory nature and complexity of diagnosis and treatment. Currently, proper treatment for chronic post-traumatic and postoperative osteomyelitis requires surgical debridement, elimination of dead space with local antibiotic delivery devices, which are obtained by implantation of antibiotic-loaded material, and systemic antibiotic therapy. Although systemic antibiotic therapy is an important part of the standard strategy, its effect can be impaired due to the poor penetration and poor blood supply at the local site of infection [2]. High-dose and long-term antibiotic therapy is related to severe systemic adverse effects, and long-term usage of antibiotics can promote the growth of bacterial drug resistance [3]. Local antibiotic therapy is one of the most described strategies for these drawbacks. It can reduce the risk of adverse effects caused by systemic antibiotic. Antibiotic-loaded bone cavity fillers which are consisted of degradable or non-degradable materials can be used for local antibiotic delivery devices. This not only fills up the bone cavity after surgical debridement, but also can reduce antibiotic concentration in serum and offer high concentration of antibiotic at the local site of infections [4‐8]. Antibiotic-loaded PMMA has been the gold standard vehicle for local antibiotic delivery in the treatment of chronic osteomyelitis, because the antibiotic delivery system can offer the advantage of local release of high antibiotic level at the site of infection, and simultaneously enable the dead space originating from surgical debridement.

However, while PMMA was wildly employed, there are some disadvantages to be found. One of these disadvantages is the fact that PMMA can offer a substrate for bacterial colonization, especially when the release of antibiotic loaded in PMMA declines over time [9] and finally becomes ineffective. Another disadvantage is that, it is difficult to achieve and maintain the required concentration of antibiotic for the desired duration of time, because the release of antibiotics loaded in PMMA will become invalid over time and the antibiotics loaded in PMMA cannot be released completely. A high release of antibiotic from PMMA showed in the initial stage, and subsequently comes to an ineffective and constant rate of elution [10]. Additionally, the two-stage revision is needed to performed for removal the PMMA because of its non-degradation. These disadvantages of non-biodegradable PMMA have led to the pursuit for absorbable antibiotic delivery alternatives. Calcium sulfate loaded with antibiotic is one of the most extensively degradable carriers employed in the treatment of chronic osteomyelitis. It can achieve obliteration of the dead space resulting from surgical debridement, and release their antibiotic completely after their entire degradation, lacking of substratum for bacterial colonization. In addition, it is not required to be removed once again, owing to their inherently biodegradable nature. A recent study revealed that the calcium sulfate particles loaded with antibiotic had equal efficacy in the treatment of chronic osteomyelitis, comparing with PMMA loaded with antibiotic [11]. Given inefficient release kinetics of PMMA, calcium sulfate pellets loaded with antibiotic can perform a zero-order release kinetics which is not beneficial to the growth of antibiotic-resistant bacterial strains, owing to leaving no prolonged, low-level tail-release of antibiotic. Moreover, as one kind of surface eroding materials, calcium sulfate primarily releases antibiotic in their outer rim through degradation layer by layer, therefore the release rates of antibiotic loaded in calcium sulfate are relatively constant and sustained at a therapeutic level during a long-term period of time. However, antibiotic delivery devices made of calcium sulfate have intrinsic disadvantages. First, calcium sulfate cannot provide structural support for the stabilization of the bony structure, especially in the gradual degradation of calcium, the mechanical support further weakening. However, the mechanical stabilization of the bony structure is considerably significant in the treatment of chronic osteomyelitis [12]. Antibiotic-loaded PMMA spacers can support the bony structure with immediate stabilization or are advantageous to the maintaining of the skeletal stabilization. Antibiotic-loaded PMMA spacers can maintain the length of the bony structure and soft-tissue at the local site of infection, owing to their non-degradation. It may be advantageous to the secondary surgical revision.

The significant progress has been made in orthopedic surgery and antibiotic therapy over the past few decades, however, the treatment of chronic post-traumatic and postoperative osteomyelitis is still a difficultly controllable clinical problem. It is considerably difficult to treat because of the factors of patient and pathogen. Besides radical surgical debridement, appropriate treatments consist of long-term systemic antibiotic therapy, local antibiotic therapy by local delivery devices which are composed of biodegradable or non-biodegradable materials, and sometimes removal of internal fixation. In the study, in order to reduce serious side effects and the occurrence of bacterial resistance, intravenous antibiotic therapy was administrated for only 3 to 4 weeks. Preoperatively, it was used for 1 week, while it was used for 2 to 3 weeks postoperatively. Nephrotoxic effects, hepatotoxic effects and other adverse reactions related to intravenous antibiotic therapy did not appear in this study. Generally, systemic antibiotic treatment cannot achieve sufficient release of antibiotic in the area of infected bone due to poor blood supply resulting from soft tissue scarring and bone sclerosis.

Compared with systemic antibiotic treatment, local antibiotic delivery systems implanted with non-biodegradable or biodegradable delivery devices possess several merits, because effective and higher antibiotic concentrations are obtained in the local area of infected bone through the systems for a prolonged period of time. In addition, the period of patient hospitalisation is significantly shortened, the adverse events related to systemic chemotherapy are availably prevented, and the risk of systemic toxicity can be reduced [14]. Local antibiotic therapies play a critical role in the treatment of chronic osteomyelitis. So, local application of bone void filler implanted with antibiotic indicated adequate local concentration of the antibiotic in the area of infected bone, simultaneously, sufficient low systemic exposure in patients suffering from chronic osteomyelitis. It has been revealed, after local application of antibiotic delivery devices, effective antibiotic concentration in the area of infected bone is available for up to 6 weeks in the surrounding tissue.

There are two types of antibiotic delivery devices, non-biodegradable delivery system and biodegradable delivery system. Frequently, the non-degradable antibiotic delivery system is consisted of PMMA carriers. Higher local antibiotic concentrations can obtain by the temporary usage of the antibiotic delivery devices, while lower systemic concentration of antibiotic can achieve, minimizing adverse events. Therefore, PMMA has rapidly turned into a standard protocol for local antibiotic delivery in the treatment of osteomyelitis. PMMA loaded with antibiotic are often used in the form of spacers, which not only increased the local concentration of antibiotics in the infected area, simultaneously minimized the level of systemic antibiotics, but also eliminated the void cavity caused by surgical debridement [14]. Furthermore, it provided immediately structural stabilization [15] that may be advantageous to the treatment of osteomyelitis. PMMA loaded with antibiotic is established as a standard in the treatment of chronic osteomyelitis, which can offer higher local antibiotic concentrations, but it has its own disadvantages, mainly because it shows burst release and consequently sub-therapeutic release kinetics, especially the level of eluted antibiotic declines over time [16]. Therefore, to achieve and maintain the desired level of the antibiotic is very difficult at the expected length of time. When the release levels of antibiotic loaded in PMMA are less than the minimum inhibitory concentration, PMMA carriers themselves can represents a potential nidus for infection and offer a substratum for bacterial colonization and biofilm formation. Bacteria in biofilms are less sensitive to antibiotics, because bacterial biofilms can impede the penetration of antibiotics [17], which may promote progression and recurrence of chronic infection. Comparing with their planktonic counterparts, bacteria in biofilms presented a 1,000-fold tolerance to antibiotics, and significant resistance to host immunity [18]. This may be a part of the reason why a growing number of osteomyelitis relapses occur and antibiotic resistance is becoming increasingly prevalent. Bacterial adhesion and sustained growth of bacteria on the surface of the antibiotic-loaded PMMA have been deeply studied [19‐21].

The research for biodegradable alternatives have become highly necessary due to these drawbacks. It is a strongly attractive alternative that the application of biodegradable devices for antibiotic delivery in the treatment of chronic osteomyelitis. Degradable devices produce a zero-order release kinetics, which will not promote the growth of antibiotic-resistant bacterial strains because of lack of long-term and sub-therapeutic concentration tail-release. A reviews including 15 studies showed an outcome range from 80 to 100% eradication in all patients where infection was absent after treatment with the use of antibiotic - impregnated bioabsorbable bone substitutes [22]. Calcium sulfate is one kind of biodegradable delivery devices which can be loaded with antibiotics. The advantages of calcium sulfate is that it can offer the chance to delivery an effective concentration of local antibiotics with the biodegradation after implantation [23‐26]. In contrast to PMMA spacers, the porous structure of calcium sulfate can make the antibiotic to sufficiently penetrate, it can be absolutely absorbed in the human tissue and has more adequate elution of antibiotics, moreover, it does not promote inflammation [27‐30]. Calcium sulfate can completely release antibiotic load in them after degradation, while absence of substratum for bacterial colonization. Recently, one study revealed that antibiotic-loaded calcium sulfate beads were able to prevent bacterial colonization, and effectively reduce biofilm formation [31]. However, calcium sulfate has its own inherent shortcomings. The absorption of calcium sulfate can occur rapidly in vivo, and the mechanical strength of the material can quickly lose with degradation [32, 33]. So, calcium sulfate are not intended to provide structural support. The degradation products of calcium sulfate carriers generally resulted in persistent drainage from the wound which may aggravate deep infection [34]. Calcium sulfate absorbs plenty of water, subsequently promote seromas formation and increase the risk of secondary infection [35]. Additionally, calcium sulfate pellets cannot be expected to replace PMMA spacers in situations where mechanical support and integrity are important to the procedure (such as spacers in staged revision).

it is envisioned that vancomycin-loaded calcium sulfate pellets can be employed in combination with vancomycin-loaded PMMA spacers in the treatment of osteomyelitis, with calcium sulfate pellets providing the opportunity to deliver higher local antibiotics concentrations with degradation and PMMA spacers providing structural strength and integrity. Radiographic analysis showed that the calcium sulfate pellets were resorbed completely in approximately 30–60 days in this study. In a recent study, local implantation of calcium sulfate beads loaded with antibiotic obtained a good therapeutic effect in the treatment of the lower-extremity osteomyelitis in the absence of systemic antibiotics [35]. In this study, we applied the advantages of PMMA spacers and calcium sulfate pellets respectively to yield synergistic anti-infection effect. The combination therapy with vancomycin-loaded calcium sulfate pellets and vancomycin-loaded PMMA spacers presented a good effect in the treatment of chronic post-traumatic and postoperative osteomyelitis in this study, comparing with PMMA spacers loaded antibiotic. In this study, the group of the combination therapy with calcium sulfate pellets and PMMA spacers showed less rate of persistent or recurrent infection and rate of reoperation because of persistent or recurrent infection than the group of PMMA spacers after the first-stage treatment (P < 0.05).

The PMMA spacers loaded with a combination of different antibiotics would potentially increase the antimicrobial spectrum. It has been revealed that PMMA cement loaded with more than one antibiotic could elevate antibiotic elution, compared to only containing one antibiotic [36, 37]. So, in the study vancomycin was loaded in PMMA power with the addition of gentamicin sulphate in order to produce a synergistic effect. In a recent paper, calcium sulfate beads loaded with more than one antibiotic could elevated and prolonged elution of vancomycin, compared with beads only containing vancomycin [38].

In conclusion, the study demonstrated the feasibility and efficacy of the combination therapy with calcium sulfate pellets loaded antibiotic and PMMA spacers loaded antibiotic in treatment of chronic post-traumatic and postoperative osteomyelitis.