Table 1.
The research progress and approaches of vascularized 3D-printed bone repair materials
| Modification | Property | Therapy model | References |
|---|---|---|---|
| Functionalized 3D printed scaffolds | |||
| Tantalum scaffold/poly dopamine/magnesium | Sustained ion release enhanced vascularized bone formation | Rat femur condyles bone defect | [96] |
| PCL/HA scaffold/Sr2+/Fe3+ | Synergetic release of Sr2 + /Fe3 + achieved bone regeneration with immunomodulation, angiogenesis, and osteogenesis | Rat cranial defect | [155] |
| TCP scaffold/SiO2 and ZnO dopants | Addition of SiO2 and ZnO to the scaffolds facilitated cellular attachment and proliferation | In vitro cell experiments | [156] |
| PCL scaffold/surface aminolysis /DFO | Controlled release of DFO achieved the rapid 3D vascularization and bone regeneration | Rat femur defect | [103] |
| MBG/PHBHHx scaffold/DMOG | Sustained DMOG release enhances the angiogenesis and osteogenesis | Rat bone defect | [157] |
| β-TCP scaffold/RGD-phage | Stable REG production induced the regeneration of vascularized bone | Rat radius defect | [160] |
| Mesoporous calcium silicate scaffold/SVVYGLR | The stable and sustained release of SVVYGLR promoted more tubular vessel formation and homogeneous new bone regeneration | Rabbit radial defect | [161] |
| Hydroxyapatite/calcium sulfate scaffold/VEGF | The stable release of VEGF improved bone regeneration and angiogenesis | Rabbit femur defect | [163] |
| PLA scaffold/gelatin and Polylysine/BMP-2/VEGF | Sequential release of BMP-2/VEGF in spatiotemporal successfully induced angiogenesis and osteogenesis | In vitro cell experiments | [164] |
| PCL scaffold/BMP-2/VEGF | Spatially and temporally delivered BMP-2 and VEGF sequentially promoted angiogenesis and bone regeneration | Subcutaneous model of mice | [165] |
| Special carrier-loaded 3D printed scaffolds | |||
| Ti6Al4V scaffold/poloxamer 407 hydrogel/simvastatin | Sustained release of simvastatin promotes osteogenesis and angiogenesis | Rabbit tibial defect | [174] |
| Gel/alginate/β-TCP scaffold PLGA microspheres/VEGF | Sustained release of VEGF promotes osteogenesis and angiogenesis | In vitro cell experiments | [178] |
| β-TCP scaffold/Gel microspheres /Liposome DFO | Controlled release of DFO promotes osteogenesis and angiogenesis | Rat femoral defect | [104] |
| PCL scaffold/exosomes/VEGF | Delivery and protection of VEGF promoted osteogenesis and angiogenesis | Rat radial defect | [182] |
| Cell-modified 3D printed scaffolds | |||
| PLA scaffold/EPCs/hBMSCs | Improved cell survival, oxygen diffusion, and nutrients. Promoted Osteogenesis and angiogenesis | In vitro cell experiments | [187] |
| PCL/HA scaffold/hydrogel ADMSC/HUVECs | Accelerated the establishment of vascular network | Subcutaneous model of mice | [189] |
| PCL/HA scaffold/SVFCs hydrogel | Short-term hypoxia promoted vascularization | Subcutaneous model of mice | [191] |
| PDACS/PCL/WJMSCs/HUVECs hydrogel scaffold | Promoted the formation of the vascular network and enhanced osteogenesis | In vitro cell experiments | [192] |
| Hyaluronic acid (HAMA)/alginate/HUVECs microvessels | Injection and suturing, be introduced into large bone repair implants for pre-vascularization and osteogenesis promotion | Subcutaneously in a murine model | [190] |
| PCL/TCP/hFASCs hydrogel scaffold | Promoted osteogenesis and vasculogenesis | Rat cranial defect | [193] |
| HUVECs/ASCs hydrogel scaffold | Promoted osteogenesis and vasculogenesis | Mice muscle implantation | [194] |
| BMP-hBMSCs/GelMA scaffold | Promoted osteogenesis and vasculogenesis | Mice muscle implantation | [195] |
| Alginate/HA/plasmid MSCs/PCL scaffold | BMP-transfected cells promoted osteogenesis and angiogenesis | Subcutaneous model of mice | [196] |
| MSCs/EVs/PLA scaffold | Increased the expression of osteogenic and angiogenic markers | Rat cranial defect | [197] |
| Bionic 3D printed scaffolds | |||
| β-TCP scaffold /MSCs/ECFCs Hydrogel | Realized central vascularization and Osteogenesis | Rabbit femoral defect | [210] |
| OCP/GelMA hydrogel/HUVECs scaffold | Simulated bone structure; accelerated osteogenesis and angiogenesis | In vitro cell experiments | [211] |
| CDHA/axial vascular pedicle scaffold | Simulated bone structure achieved osteogenesis and angiogenesis | Sheep large bone defect | [212] |
| PLGA/β-TCP/CMs AV bundle scaffold | Combined of an AV bundle and rhBMP-2 | Rabbit intramuscular pocket | [213] |
| Bioceramics/autologous total bone marrow/femoral vein scaffold | Illustrated the capacity of an intrinsic vascularization by a single vein to support ectopic bone formation | Subcutaneous model of mouse, sheep, rat, rabbit | [214] |
| AKT hollow-channel scaffold | Multi-channel structure achieved osteogenesis and angiogenesis | Rabbit cranial defect; Rat muscle implantation | [215] |
| BRT-H scaffold | Hollow-pipe structure with bioactive ions accelerated osteogenesis and vascularization | Rabbit radius segmental defect | [216] |
| AKT/bio-ceramic/bioactive glass scaffold | Haversian bone–mimicking scaffold promoted osteogenesis and angiogenesis | Rabbit femoral defect | [217] |