Purpose: To investigate the effect of pressurizing vertebral bodies during vertebroplasty using different materials in the development of fat embolism (FE) and any associated cardiovascular changes.

Polymethylmethacrylate (PMMA) is the material of choice for vertebroplasty (VP). However, PMMA has several disadvantages such as exothermic curing, uncertain long-term biomechanical effects and biocompatibility. As a result alternative materials are being developed to overcome these problems.

In order to determine the role of PMMA in the generation of cardiovascular changes following vertebroplasty we compared injection of cement with wax in an animal model.

Method: In twenty sheep, four vertebral bodies were augmented either with PMMA or bone wax. Heart rate, arterial, central venous and pulmonary artery pressure, cardiac output and blood gas values were recorded. At postmortem the lungs were subjected to histological evaluation.

Results: The consecutive augmentation of four vertebral bodies with PMMA induced cumulative fat embolism causing significant deterioration of baseline mean arterial blood pressure (MABP) and blood gas values. Injection of bone wax resulted in similar cardiovascular changes and amount of intravascular fat in the lungs.

Conclusion: In this animal model cardiovascular complications during multiple VP happen regardless of the augmentation material used. The deteriorating baseline MABP during VP is associated with the pressurization and displacement of bone marrow/fat into the circulation rather than caused by polymethylmethacrylate.

To investigate the effect of pressurizing vertebral bodies during vertebroplasty using different materials in the development of fat embolism (FE) and any associated cardiovascular changes.

Polymethylmethacrylate (PMMA) is the material of choice for vertebroplasty (VP). However, PMMA has several disadvantages such as exothermic curing, uncertain long-term biomechanical effects and biocompatibility. As a result alternative materials are being developed to overcome these problems.

In order to determine the role of PMMA in the generation of cardiovascular changes following vertebroplasty we compared injection of cement with wax in an animal model.

In twenty sheep, four vertebral bodies were augmented either with PMMA or bone wax. Heart rate, arterial, central venous and pulmonary artery pressure, cardiac output and blood gas values were recorded. At postmortem the lungs were subjected to histological evaluation.

The consecutive augmentation of four vertebral bodies with PMMA induced cumulative fat embolism causing significant deterioration of baseline mean arterial blood pressure (MABP) and blood gas values. Injection of bone wax resulted in similar cardiovascular changes and amount of intravascular fat in the lungs.

Conclusion: In this animal model cardiovascular complications during multiple VP happen regardless of the augmentation material used. The deteriorating baseline MABP during VP is associated with the pressurization and displacement of bone marrow/fat into the circulation rather than caused by polymethylmethacrylate.

The ability to assess the blood flow to a bone (IBF) is important for orthopaedic surgeons when deciding the fate of an injured or diseased bone. Currently there is no easy and effective method for quickly assessing the blood flow status of a bone. There is accumulating evidence that suggests that IBF may be correlated to intraosseous pressure (IOP).

Therefore, we aimed to investigate whether the two variables are correlated so that the orthopaedic surgeon could confidently use IOP as an indicator of IBF.

Using 8 mature female ewes (B.W. ~56 kg) we measured cardiovascular (eg. arterial blood pressure – ABP), and intraosseous (ie. IOP and IBF) responses to nor-adrenaline (0–1.5 μg/kg/min. i.v.) and nitroglycerine (0–80 μg/kg. i.v.) IBF was measured using semi-quantitative technique of laser Doppler flowmetry (LDF).

Our results revealed that changes in ABP were directly correlated to changes in IOP (p < 0.001). Due to technical difficulties that were encountered when using LDF, the collected IBF data were limited. However, there was compelling evidence that there is a positive and direct correlation between IBF and IOP.

This opens an exciting possibility of using IOP for quickly and accurately assessing IBF as well as providing insight into the pathological mechanisms responsible for bone and joint disorders.

We carried out a histological study of a proximally hydroxyapatite (HA)-coated femoral component, retrieved after 9.5 years of good function. The HA coating had completely degraded. Bone was in direct contact with the titanium surface in all the areas which had been coated, with no interposing fibrous tissue. There were no signs of particles, third-body wear, adverse tissue reactions or osteolysis. Bone remodelling was evident by the presence of resorption lacunae; tetracycline labelling showed bone laid down six years after implantation.

The loss of the HA-coating had no negative effect on the osseo-integration of the stem. We conclude that the HA coating contributes to the fixation of the implant and that its degradation does not adversely affect the long-term fixation.