Osteoporosis is the most prevalent bone disease worldwide and represents an increasing challenge in spinal surgery, contributing to the complexity of surgical interventions and affecting the patient outcomes.1,2 As the global population ages, the incidence of osteoporosis is projected to further increase, and thus, its impact on spinal health and healthcare systems is becoming an increasingly pertinent issue.1,3 This systematic skeletal disease is characterized by a decreased bone density and the degradation of bone microarchitecture, which significantly increases the fracture risk.4 Furthermore, the decreased bone quality complicates the treatment of spinal fixation and fusion procedures, particularly in the context of pedicle screw fixation strength and the success of vertebral body replacement (VBR).5 The inherent weakness of osteoporotic bone compromises the efficacy of conventional fixation techniques, necessitating innovative approaches to improve construct stability and ensure successful patient recovery.6

Cement augmentation techniques have shown promising results in the treatment of osteoporotic spines, facilitating the management of vertebral fractures through vertebroplasty or kyphoplasty and enhancing the stability of constructs, notably in the implantation of pedicle screws within osteoporotic vertebrae.7,8 Therefore, these procedures gained increasingly popularity within the last three decades, leading to an increased number of cementation procedures in spinal surgery.9 However, the utilization of cement augmentation remains a topic of ongoing debate among spinal surgeons due to associated severe complications. An increase in stiffness enhances the risk of adjacent segment fractures, and the treatment of potential deep wound infections becomes more challenging. The most common risk involves cement leakages, with incidences reported up to 90% in pedicle screw augmentation, which are mostly asymptomatic.10,11 However, in rare cases, these leakages can lead to fatal pulmonary artery embolism or, when leaking into the spinal canal, injury of neural structures, potentially resulting in paralysis.12,13 Consequently, the use of cement augmentation techniques must be approached with caution, ultimately to improve patient care in the context of the challenging increase of patients requiring spinal surgery while suffering from osteoporosis.

The aim of this study is to share a comprehensive compilation of tips and tricks for using cement augmentation of pedicle screws and VBR, garnered from our clinical experience as well as from biomechanical and clinical studies, highlighting the nuanced strategies that can reduce the complication rate and, thus, optimize the surgical outcome following cement augmentation procedures in osteoporotic spine patients.

We conducted a comprehensive review of relevant literature to aggregate and analyze existing biomechanical and clinical studies on the application of cement augmented vertebral fixation for patients who have osteoporosis. Our search aimed to encompass research articles published in English, German, or Spanish in peer-reviewed journals without any temporal restriction. Additionally, we reviewed guidelines and systematic reviews related to cement augmentation to extract further recommendations. These findings are presented for (1) cement augmentation of pedicle screws and (2) cement augmentation of VBR, augmented by the authors’ own clinical experiences.

To effectively fill the gap between theoretical knowledge and practical application, we selected two case reports from our institutional database that illustrate the use of cement augmentation in VBR procedures. These cases were specifically chosen for their ability to illustrate the application, benefits, challenges, and outcomes of these techniques in distinct patient scenarios.

While the cement augmentation of dorsally implanted pedicle screws is widely practiced and has become a standard part of a spinal surgeon's repertoire, cement augmentation of VBR currently plays a minor role in the clinical practice of most surgeons. In 2010, Geiger et al. first described the feasibility of cement augmentation for VBR in a clinical study involving 20 patients, with clinical and radiological follow-up over two years.42 The study group aimed to prevent or reduce the likelihood of collapse in VBR cases with reduced bone quality. For this technique, the patient is positioned in a lateral decubitus after dorsal fixation. To access vertebral body fractures above the second lumbar vertebra, a transpleural approach combined with a diaphragmatic split is often performed. For vertebral body fractures involving the second lumbar vertebra or below, a mini-open extraperitoneal approach is performed, and standard VBR is conducted. When preparing the VBR care must be taken to preserve the subchondral bone of the adjacent endplates. After successful implantation of the cage, a 10-G vertebroplasty needle can be placed half a centimeter above the endplate of the lower and half a centimeter below the endplate of the upper vertebra through the already open approach, under the surgeon's direct vision. Cement augmentation is then carried out under pulsed lateral fluoroscopy guidance. Beyond this initial description, only a few studies have been published. However, biomechanical investigations suggest that cement augmentation significantly increases construct stability.43,44 According to Ullrich et al. PMMA endplate augmentation should be performed when bone HU are below 180.45

As an example, we chose the described approach for an 81-year-old patient presenting to our clinic with a pathological L4 fracture due to metastatic bronchial carcinoma (Fig. 2). Following radiation therapy, there was a progressive compression and instability of the vertebral body as a result of radiation-induced vertebral necrosis. Due to accompanying symptomatic spinal canal stenosis with right-sided lumbar sciatica from neuroforaminal and lateral recess stenosis, a dorsal percutaneous spondylodesis from L3 to L5 with cement-augmented pedicle screws was performed, along with a dorsal hemilaminectomy of the fourth lumbar vertebra with facetectomy and decompression of the right L4 and L5 nerve roots. Subsequently, after repositioning the patient, VBR (Obelisk, Ulrich Medical) with cementation of the endplates was conducted under direct vision as previously described.42 Ten days postoperatively, the patient was discharged for outpatient treatment. Follow-up examinations showed a satisfactory outcome.

Figure 2.

Vertebral body replacement L4. (A) Pathological L4 fracture due to metastatic bronchial carcinoma. (B) Lateral X-ray following short segment fixation with cement augmented pedicle screws and VBR with endplate cementation. (C) Anteroposterior view.

(0.16MB).

Another case involved a 71-year-old female patient who presented after falling from a horse, sustaining a traumatic Th12 fracture (Fig. 3). X-rays revealed degenerative lumbar scoliosis (Cobb angle 19°). Despite a T-score of −1.9, we opted for cement-augmented short segment fixation for this mobile and active patient, and due to recurrent axial traumas from horseback riding, we decided on additional cementation of the endplates. The procedure was performed in two stages without complications. One year postoperatively, the patient reported being able to horseback ride unrestrictedly, and despite the short-segment fusion at the thoracolumbar junction the most recent five-year follow-up showed an uneventful and satisfactory clinical and radiological outcome.

Figure 3.

Traumatic Th12 fracture. (A/B) Preoperative CT scan. (C/D) Postoperative CT scan following short segment fixation with cement augmented pedicle screws and VBR with endplate cementation. (E) Stand up X-ray (coronal view) at last follow up. The lumbar scoliosis remained constant. The patient was fully functional and had no restraints in daily activities five years postoperatively.

(0.16MB).

Amidst the demographic shift toward an aging global population, not only is the necessity for spinal procedures expected to increase overall, but there is also an anticipated increase in the number of spinal interventions requiring cement augmentation due the rising incidence of osteoporotic spinal fractures. Although cement augmentation may initially seem daunting to young surgeons due to potentially severe complications, extended surgery duration, and more demanding techniques, the decision to use cement often proves beneficial in the long run. With careful patient selection and adherence to the experiences accumulated over recent decades, cement augmentation of pedicle screws is generally a feasible and safe procedure that significantly reduces the need for revision surgeries due to implant failure. Furthermore, cement augmentation of endplates provides an effective method for VBR, preventing the collapse of the rigid construct even in short segment dorsoventral approaches. Future research, such as on antibiotic loaded PMMA, may further expand its utility and safety profile, especially for high-risk patients such as those that need spinal fixation due to tumor or revision surgery.

Level of evidence iii.

All procedures performed in studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards.

No funding was received for this research.

Informed consent was obtained from all individual participants included in the study.

The authors declare that they do not have conflicts of interest.