We hereby present a novel pathological study of sternal osteomyelitis after cardiac surgery. The histological sections showed an overwhelming dissemination of the inflammation across all anatomical parts and across both hemisternums.
DSWI implies the extension of the infection beyond the muscle fascia. These infections usually extend into the anterior mediastinum and involve the soft tissues (skin, subcutaneous tissue, muscle, thymus, pleura, pericardia) and the bone [4]. The development of DSWI may occur due to a combination of factors, which could be classified into bacterial contamination, insufficient blood supply, patient comorbidities and surgical circumstances [6]. The bone involvement may occur therefore due to the contamination with highly pathogen bacteria like Staphylococcus aureus, but also due to less pathogen germs like coagulase-negative staphylococci [3]. While a well perfused cancellous bone in a healthy individual would resist bacterial contamination, this could not be the case in devascularized bone in a multimorbid patient. Whereas the infection may begin at the level of the soft tissues or within a retrosternal hematoma, the involvement of the defenseless bone will complicate the course of the disease. Not all DSWI imply a sternal osteomyelitis. If the soft tissue infection is treated promptly and the collections are drained, a secondary closure of the sternum and the soft tissues is possible [7]. On the other hand, once the bone is involved in the infection with transversal fractures and development of sequester, the soft tissue infection will be maintained indefinitely by the SO. In these cases, a radical sternectomy is necessary to treat the infection [5].
Patients with DSWI not only have a heart condition, but mostly have other comorbidities like diabetes mellitus, obesity or occlusive peripheral arterial disease, which further complicate the DSWI treatment. A swift treatment of the infection is therefore the key to successful treatment. By removing the infected sternal bone en bloc, our team facilitated for the first time the examination of the whole sternum in 47 patients. The results showed that the inflammation extended to most of the sternal bone, from the manubrium to the xyphoid and from the sternotomy margin to the rib cartilages. The more precise examination using different degrees of bone inflammation, from fibrosis to acute purulent osteomyelitis showed a ubiquitous distribution of the different types of inflammation, without significant differences between the two hemisternums. When considering the anatomical parts of the sternum, a tendency towards higher degrees of inflammation of corpus sterni was observed, especially on the left side. With the first model this finding could not be confirmed, all anatomical parts being comparably affected by inflammation. This finding has a particular surgical importance. The manubrium stretches laterally towards the first and second ribs and is wider than the caudal sternum. The partial sternectomy does not usually reach the first and second ribs and according to our current findings is probable to leave infected bone in place. Even if this lateral bone and the rib joints will not have a purulent infection, it is according to our results with high probability infected and should be resected to avoid infection relapse.
The harvest of the LIMA for coronary artery bypass is common and offers improved long-term results [8]. Several anatomic studies have shown different anatomical patterns of the internal mammary artery branches to the sternum and intercostal spaces. The common recommendation is the ligation of the branches close to the main trunk (skeletonization), to preserve the collateral circulation [9, 10]. Harvesting the main source of blood supply to the sternum has been shown in different studies to decrease the vascularization, using laser doppler Flowmetry and remission spectrometry [11] or infrared thermography [12]. The skeletonization of the LIMA was proven in a meta-analysis to decrease the incidence of sternal wound infections [13]. Kamiya et al have shown a drop in retrosternal microcirculation using laser doppler Flowmetry and remission spectrometry, with a significant difference between skeletonized and pedicled LIMA [14], while a similar study proved only the drop in microcirculation with similar results for both pedicled and skeletonized LIMA cases [15]. Using bone scintigraphy, Korbmacher et al found no perfusion impairment on the LIMA side, although the contralateral side showed an increase in perfusion as a compensatory sign. A similar study in patients BIMA harvest showed a significant drop in sternal perfusion only in the diabetic subgroup [16], which could be explained by the missing redistribution of circulation in patients with microangiopathy. All this data points to the idea that the development of SO is a multifactorial process, where contamination, blood supply and comorbidities play a collective role in the pathogenesis. In our study, when considering all examined specimens, LIMA harvest had a significant influence on the level of inflammation on the left side of the manubrium in both models. When analyzing the two hemisternums in the 32 patients with LIMA harvest, the left side of the manubrium showed again significantly more inflammation, but only in the second model. These limited findings could confirm the theory that the sternal devascularization plays a key role in the development of DSWI. On the other hand, the involvement of the right side, where the mammary artery was not harvested, indicates that the pathogenesis of SO involves other factors besides the alteration of blood supply. One theory would be that the devascularized bone is first infected and the infection spreads to the healthy bone over time, facilitated by the presence of foreign bodies (osteosynthesis wires), infected fluid collections and infected soft tissues.
We further investigated the risk factors known to favor the development of surgical site infections and DSWI, like patient-related factors (smoking, alcohol consumption, diabetes mellitus and insulin intake, myocardial infarction, heart failure, endocarditis, ASA classification) or surgery-related factors (coronary bypass surgery, heart valve surgery and prosthetic aortic replacement) [6], without finding a statistical correlation. As opposed to LIMA harvest, these factors have an overall impact on DSWI and therefore are not expected to have an impact on one specific anatomical region or side of the sternum.
While multiple case reports and case series describe the primary osteomyelitis, which occurs mostly in children and in immunosuppressed patients with common germs like Staphylococcus aureus or with atypical germs like Mycobacterium tuberculosiss [2, 17–22], the literature is very restrictive in describing the pathology of secondary SO, most studies concentrating on the prevention, epidemiology, microbiology and treatment of DSWI [6, 23].
The DSWI often extends not only to the sternal bone, but also to the rib cartilages [24], where the infection may persist in the case of an incomplete debridement. After the en bloc resection, we resect the protruding ribs and the sternoclavicular joints on each side. These rib parts could not be systematically examined, which might present a limitation of our study and a direction to further research, in order state the exact extent of the infection beyond the sternal bone.