The human musculoskeletal system is a biological composite of hard and soft material phases organized into a complex 3D structure. The replication of mechanical properties in 3-dimensional space, so called ‘4D’ techniques, therefore promises next-generation of prosthetics and engineering structures for the musculoskeletal system. Approaches using in situ indentation of tissue correlated with micro computed tomography (μCT) are used here to provide a 4D data set that is representative of the native tissue at high fidelity. Multi-material 3D printing is exploited to realize the collected 4D data set by using materials with a wide range of mechanical properties and printing structures representative of native tissue. We demonstrate this correlative approach to reproduce bone structures and highlight a workflow approach of indentation, μCT and 3D printing to potentially mimic any structure found in the musculoskeletal system.

Structures in the human musculoskeletal system, such as bone [1] and tendon-bone connective tissue [2], can be considered as complex composites of hard and soft materials. Development of prosthetics capable of replacing body parts lost to trauma, disease or congenital conditions requires the accurate replication of the required body part. 3D printing promises considerable advantages over other manufacturing methods in mimicking native tissue, including the ability to produce complex structures [3]. However, accurate representation of whole body parts down to tissue microstructures requires correlative approaches where mechanical properties in 3-dimensional space are known. The objective of this study is to apply in situ indentation, correlate to 3D imaging of bone using μCT and finally 3D print mimicked structures.

Samples of bovine compact bone were imaged at high resolution using μCT (Xradia Versa 510, Zeiss, USA). A custom build in situ micro indentation setup within the μCT was used to map the mechanical properties of the bone at multiple positions. Correlation between sample x-ray attenuation and corresponding elastic modulus found from indentation was established. Data was converted to a 4D data set of elastic modulus values in 3D space, segmented and exported to the 3D printer. An inkjet 3D printer (Projet 5500X, 3D Systems, USA) was used to print materials with a range of mechanical properties that approach those found in the native bone material. Macroscopic testing on both bone samples and 3D printed samples were carried out using standard compression (Instron, UK).

Preliminary results indicated similarity between 3D printed structures and native bone tissue. Macroscopic testing of bone samples and 3D printed equivalents showed additional similarities in stress-strain behaviour.

Our preliminary work presented here indicates that the workflow of 3D imaging correlated to point mechanical measurements using indentation is suitable to give a 4D dataset that is representative of the native bone tissue. 3D printing is able to produce structures that start to mimick bone but are critically dependent on the data segmentation, particularly averaging imaging data to a resolution that is appropriate for the 3D printer.

3D printing can be used for the regeneration of complex tissues with intricate 3D microarchitecture. Trabecular bone is a complex and porous structure with a high degree of anisotropy. Changes in bone microarchitecture are associated with pathologies such as osteoporosis [1]. The objective of this study is to determine the viability of using 3D printing to replicate trabecular bone structures with a good control over the microarchitecture and mechanical properties.

Cylindrical samples of bovine trabecular bone were used in this study. Micro-computed tomography (microCT) was carried out and an isotropic voxel size of 22 µm was obtained (Xradia Versa 520, Zeiss, USA). After 3D reconstruction the main microstructure characteristics were analysed using ImageJ (NIH, US).

The 3D printed bone replicas were created by segmenting the microCT imaged bone tissue and then converted into a STL file using Avizo (FEI, US). The 3D printer used for this study was the ProJet 5500X (3D Systems, US), which allows a number of different materials to be printed in the same built with a resolution of 25 µm. Preliminary results were obtained using one single material (VisiJet CR-WT, Tensile Modulus: 1–1.6 GPa, Tensile Strength: 37–47 MPa). The 3D printed bone replicas followed a critical cleaning step to remove any remaining support material in the pores. MicroCT was then carried out for the bone replicas obtaining the same isotropic voxel size as for their biological counterparts. ImageJ was used to obtain the main microstructure characteristics.

The values of bone volume fraction (BV/TV), mean trabecular thickness (Tb.Th), mean trabecular spacing (Tb.Sp), and degree of anisotropy (DA) were measured for bone samples and their 3D printed replicas [2].

Preliminary results on the first bone sample with its 3D printed replica showed similar apparent trabecular structures. Their respective BV/TV was found to be 0.24 (bone) and 0.43 (replica). The Tb.Th and Tb.Sp were 0.222 mm and 0.750 mm respectively for the bone and 0.376 mm and 0.575 mm for the replica. Finally, their respective DA was found to be 0.68 (bone) and 0.66 (replica).

The main microstructure characteristics analyzed showed some differences between the bone sample and the 3D printed replica. In particular, the 3D microstructures resulted over-dimensioned mainly due to factors such as microCT voxel size, resolution of the 3D printer and supporting material removal. However this is a preliminary investigation. Further analysis will focus on optimizing the microCT imaging as well as the 3D printing process to achieve more accurate bone replicas. In addition, multi-material printing will be employed to optimize some of the mechanical properties obtained through in situ microCT testing and FE subject-specific modelling.

The aim of this study was to evaluate a new joint arthroplasty clinical priority scoring tool.

A new arthroplasty scoring tool based on pain, function, social limitation, potential of benefit from surgery and consequence of more than 6 months delay was developed and evaluated using 16 patient scenarios (vignettes) related to hip and knee osteoarthritis. Sixteen orthopaedic surgeons were asked to score the vignettes using clinical ranking, ISS tool and the new tool.

Significant variation in ranks allocated by surgeons was recorded for all three tools. Vignettes at either end of the scale ie. those who are severely or minimally disabled had less variability compared to a large group in the middle range. Comparing the three tools there did not appear to by any advantage of one over the other. Most of the variations occurred in the interpretation of benefit from the operation and consequence of delay.

Scoring tools rely heavily on judgement based decisions. More work is required to understand judgement processes used by surgeons and audit/feedback mechanisms may help in reducing the variations in priority assignment.