Your search keyword '"Jakus AE"' showing total 25 results

1. Preclinical Safety of a 3D-Printed Hydroxyapatite-Demineralized Bone Matrix Scaffold for Spinal Fusion.

Author

Plantz M, Lyons J, Yamaguchi JT, Greene AC, Ellenbogen DJ, Hallman MJ, Shah V, Yun C, Jakus AE, Procissi D, Minardi S, Shah RN, Hsu WK, and Hsu EL

Subjects

Animals, Female, Rats, Bone Morphogenetic Protein 2, Bone Transplantation, Durapatite, Lumbar Vertebrae diagnostic imaging, Lumbar Vertebrae surgery, Printing, Three-Dimensional, Prospective Studies, Rats, Sprague-Dawley, Recombinant Proteins, Transforming Growth Factor beta, Bone Matrix, Spinal Fusion methods

Abstract

Study Design: Prospective, randomized, controlled preclinical study., Objective: The objective of this study was to compare the host inflammatory response of our previously described hyperelastic, 3D-printed (3DP) hydroxyapatite (HA)-demineralized bone matrix (DBM) composite scaffold to the response elicited with the use of recombinant human bone morphogenetic protein-2 (rhBMP-2) in a preclinical rat posterolateral lumbar fusion model., Summary of Background Data: Our group previously found that this 3D-printed HA-DBM composite material shows promise as a bone graft substitute in a preclinical rodent model, but its safety profile had yet to be assessed., Methods: Sixty female Sprague-Dawley rats underwent bilateral posterolateral intertransverse lumbar spinal fusion using with the following implants: 1) type I absorbable collagen sponge (ACS) alone; 2) 10 μg rhBMP-2/ACS; or 3) the 3DP HA-DBM composite scaffold (n = 20). The host inflammatory response was assessed using magnetic resonance imaging, while the local and circulating cytokine expression levels were evaluated by enzyme-linked immunosorbent assays at subsequent postoperative time points (N = 5/time point)., Results: At both 2 and 5 days postoperatively, treatment with the HA-DBM scaffold produced significantly less soft tissue edema at the fusion bed site relative to rhBMP-2-treated animals as quantified on magnetic resonance imaging. At every postoperative time point evaluated, the level of soft tissue edema in HA-DBM-treated animals was comparable to that of the ACS control group. At 2 days postoperatively, serum concentrations of tumor necrosis factor-α and macrophage chemoattractant protein-1 were significantly elevated in the rhBMP-2 treatment group relative to ACS controls, whereas these cytokines were not elevated in the HA-DBM-treated animals., Conclusion: The 3D-printed HA-DBM composite induces a significantly reduced host inflammatory response in a preclinical spinal fusion model relative to rhBMP-2.Level of Evidence: N/A., (Copyright © 2021 Wolters Kluwer Health, Inc. All rights reserved.)

Published

2022

2. Regional gene therapy for bone healing using a 3D printed scaffold in a rat femoral defect model.

Author

Kang HP, Ihn H, Robertson DM, Chen X, Sugiyama O, Tang A, Hollis R, Skorka T, Longjohn D, Oakes D, Shah R, Kohn D, Jakus AE, and Lieberman JR

Subjects

Animals, Male, Pilot Projects, Rats, Rats, Inbred Lew, Bone Morphogenetic Protein 2 biosynthesis, Bone Morphogenetic Protein 2 genetics, Bone Regeneration drug effects, Bone Regeneration genetics, Femur injuries, Femur metabolism, Genetic Therapy, Osteogenesis, Printing, Three-Dimensional, Tissue Scaffolds chemistry

Abstract

At the present time there are no consistently satisfactory treatment options for some challenging bone loss scenarios. We have previously reported on the properties of a novel 3D-printed hydroxyapatite-composite material in a pilot study, which demonstrated osteoconductive properties but was not tested in a rigorous, clinically relevant model. We therefore utilized a rat critical-sized femoral defect model with a scaffold designed to match the dimensions of the bone defect. The scaffolds were implanted in the bone defect after being loaded with cultured rat bone marrow cells (rBMC) transduced with a lentiviral vector carrying the cDNA for BMP-2. This experimental group was compared against 3 negative and positive control groups. The experimental group and positive control group loaded with rhBMP-2 demonstrated statistically equivalent radiographic and histologic healing of the defect site (p > 0.9), and significantly superior to all three negative control groups (p < 0.01). However, the healed defects remained biomechanically inferior to the unoperated, contralateral femurs (p < 0.01). When combined with osteoinductive signals, the scaffolds facilitate new bone formation in the defect. However, the scaffold alone was not sufficient to promote adequate healing, suggesting that it is not substantially osteoinductive as currently structured. The combination of gene therapy with 3D-printed scaffolds is quite promising, but additional work is required to optimize scaffold geometry, cell dosage and delivery., (© 2021 Wiley Periodicals LLC.)

Published

2021

3. Building Organs Using Tissue-Specific Microenvironments: Perspectives from a Bioprosthetic Ovary.

Author

Henning NFC, Jakus AE, and Laronda MM

Subjects

Female, Humans, Regenerative Medicine, Cellular Microenvironment, Extracellular Matrix metabolism, Ovary, Prostheses and Implants trends, Tissue Engineering

Abstract

Recent research in tissue engineering and regenerative medicine has elucidated the importance of the matrisome. The matrisome, effectively the skeleton of an organ, provides physical and biochemical cues that drive important processes such as differentiation, proliferation, migration, and cellular morphology. Leveraging the matrisome to control these and other tissue-specific processes will be key to developing transplantable bioprosthetics. In the ovary, the physical and biological properties of the matrisome have been implicated in controlling the important processes of follicle quiescence and folliculogenesis. This expanding body of knowledge is being applied in conjunction with new manufacturing processes to enable increasingly complex matrisome engineering, moving closer to emulating tissue structure, composition, and subsequent functions which can be applied to a variety of tissue engineering applications., Competing Interests: Declaration of Interests A.J. is a co-founder and CTO of the company, Dimension Inx., and has ownership and other financial interests in this company. Dimension Inx. did not influence the contents of this article. The other authors declare no conflicts of interest., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

4. Osteoinductivity and biomechanical assessment of a 3D printed demineralized bone matrix-ceramic composite in a rat spine fusion model.

Author

Plantz MA, Minardi S, Lyons JG, Greene AC, Ellenbogen DJ, Hallman M, Yamaguchi JT, Jeong S, Yun C, Jakus AE, Blank KR, Havey RM, Muriuki M, Patwardhan AG, Shah RN, Hsu WK, Stock SR, and Hsu EL

Subjects

Animals, Bone Matrix, Bone Morphogenetic Protein 2, Bone Transplantation, Ceramics pharmacology, Female, Lumbar Vertebrae, Printing, Three-Dimensional, Rats, Rats, Sprague-Dawley, Recombinant Proteins, Transforming Growth Factor beta, Spinal Fusion

Abstract

We recently developed a recombinant growth factor-free bone regenerative scaffold composed of stoichiometric hydroxyapatite (HA) ceramic particles and human demineralized bone matrix (DBM) particles (HA-DBM). Here, we performed the first pre-clinical comparative evaluation of HA-DBM relative to the industry standard and established positive control, recombinant human bone morphogenetic protein-2 (rhBMP-2), using a rat posterolateral spinal fusion model (PLF). Female Sprague-Dawley rats underwent bilateral L4-L5 PLF with implantation of the HA-DBM scaffold or rhBMP-2. Fusion was evaluated using radiography and blinded manual palpation, while biomechanical testing quantified the segmental flexion-extension range-of-motion (ROM) and stiffness of the fused segments at 8-weeks postoperatively. For mechanistic studies, pro-osteogenic gene and protein expression at 2-days and 1-, 2-, and 8-weeks postoperatively was assessed with another cohort. Unilateral fusion rates did not differ between the HA-DBM (93%) and rhBMP-2 (100%) groups; however, fusion scores were higher with rhBMP-2 (p = 0.008). Both treatments resulted in significantly reduced segmental ROM (p < 0.001) and greater stiffness (p = 0.009) when compared with non-operated controls; however, the degree of stabilization was significantly higher with rhBMP-2 treatment relative to the HA-DBM scaffold. In the mechanistic studies, PLGA and HA scaffolds were used as negative controls. Both rhBMP-2 and HA-DBM treatments resulted in significant elevations of several osteogenesis-associated genes, including Runx2, Osx, and Alp. The rhBMP-2 treatment led to significantly greater early, mid, and late osteogenic markers, which may be the mechanism in which early clinical complications are seen. The HA-DBM scaffold also induced osteogenic gene expression, but primarily at the 2-week postoperative timepoint. Overall, our findings show promise for this 3D-printed composite as a recombinant growth factor-free bone graft substitute for spinal fusion. STATEMENT OF SIGNIFICANCE: Despite current developments in bone graft technology, there remains a significant void in adequate materials for bone regeneration in clinical applications. Two of the most efficacious bone graft options are the gold-standard iliac crest bone graft and recombinant human-derived bone morphogenetic protein-2 (rhBMP-2), available commercially as Infuse™. Although efficacious, autologous graft is associated with donor-site morbidity, and Infuse™ has known side effects related to its substantial host inflammatory response, possibly associated with a immediate, robust osteoinductive response. Hence, there is a need for a bone graft substitute that provides adequate osteogenesis without associated adverse events. This study represents a significant step in the design of off-the-shelf growth factor-free devices for spine fusion., Competing Interests: Declaration of Competing Interest M.A.P., S.M., J.G.L., A.G., D.E., M.H., J.Y., S.J., C.Y., K.R.B., R.M.H., M.M., A.G.P., W.K.H., S.R.S., and E.L.H. have nothing to disclose that may create a conflict of interest within this body of work. A.E.J. and R.N.S. are cofounders of the company Dimension Inx, LLC – which aims to create biomaterials, including 3D-printed biologically active materials, that induce tissue regeneration and repair – including some of the materials discussed in this paper. As of October 2020, A.E.J. is the Chief Technology Officer (CTO) and R.N.S. is the Chief Science Officer (CSO) of Dimension Inx, LLC. The trademark for Hyperelastic Bone® is owned by Dimension Inx. The study design, reporting of data, and interpretation of data in this body of work was not influenced by the interests of Dimension Inx LLC., (Copyright © 2021. Published by Elsevier Ltd.)

Published

2021

5. 3D-Printed Ceramic-Demineralized Bone Matrix Hyperelastic Bone Composite Scaffolds for Spinal Fusion.

Author

Driscoll JA, Lubbe R, Jakus AE, Chang K, Haleem M, Yun C, Singh G, Schneider AD, Katchko KM, Soriano C, Newton M, Maerz T, Li X, Baker K, Hsu WK, Shah RN, Stock SR, and Hsu EL

Subjects

Animals, Durapatite chemistry, Humans, Rats, Rats, Sprague-Dawley, X-Ray Microtomography, Bone Substitutes chemistry, Printing, Three-Dimensional, Spinal Fusion methods

Abstract

Although numerous spinal biologics are commercially available, a cost-effective and safe bone graft substitute material for spine fusion has yet to be proven. In this study, "3D-Paints" containing varying volumetric ratios of hydroxyapatite (HA) and human demineralized bone matrix (DBM) in a poly(lactide-co-glycolide) elastomer were three-dimensional (3D) printed into scaffolds to promote osteointegration in rats, with an end goal of spine fusion without the need for recombinant growth factor. Spine fusion was evaluated by manual palpation, and osteointegration and de novo bone formation within scaffold struts were evaluated by laboratory and synchrotron microcomputed tomography and histology. The 3:1 HA:DBM composite achieved the highest mean fusion score and fusion rate (92%), which was significantly greater than the 3D printed DBM-only scaffold (42%). New bone was identified extending from the host transverse processes into the scaffold macropores, and osteointegration scores correlated with successful fusion. Strikingly, the combination of HA and DBM resulted in the growth of bone-like spicules within the DBM particles inside scaffold struts. These spicules were not observed in DBM-only scaffolds, suggesting that de novo spicule formation requires both HA and DBM. Collectively, our work suggests that this recombinant growth factor-free composite shows promise to overcome the limitations of currently used bone graft substitutes for spine fusion. Impact Statement Currently, there exists a no safe, yet highly effective, bone graft substitute that is well accepted for use in spine fusion procedures. With this work, we show that a three-dimensional printed scaffold containing osteoconductive hydroxyapatite and osteoinductive demineralized bone matrix that promotes new bone spicule formation, osteointegration, and successful fusion (stabilization) when implemented in a preclinical model of spine fusion. Our study suggests that this material shows promise as a recombinant growth factor-free bone graft substitute that could safely promote high rates of successful fusion and improve patient care.

Published

2020

6. Three-Dimensionally Printed Hyperelastic Bone Scaffolds Accelerate Bone Regeneration in Critical-Size Calvarial Bone Defects.

Author

Huang YH, Jakus AE, Jordan SW, Dumanian Z, Parker K, Zhao L, Patel PK, and Shah RN

Subjects

Animals, Cone-Beam Computed Tomography, Disease Models, Animal, Elasticity, Humans, Male, Osteogenesis, Polylactic Acid-Polyglycolic Acid Copolymer chemistry, Printing, Three-Dimensional, Rats, Rats, Sprague-Dawley, Skull diagnostic imaging, Skull injuries, Skull physiology, Treatment Outcome, X-Ray Microtomography, Bone Regeneration, Orthopedic Procedures methods, Plastic Surgery Procedures methods, Skull surgery, Tissue Scaffolds chemistry

Abstract

Background: Autologous bone grafts remain the gold standard for craniofacial reconstruction despite limitations of donor-site availability and morbidity. A myriad of commercial bone substitutes and allografts are available, yet no product has gained widespread use because of inferior clinical outcomes. The ideal bone substitute is both osteoconductive and osteoinductive. Craniofacial reconstruction often involves irregular three-dimensional defects, which may benefit from malleable or customizable substrates. "Hyperelastic Bone" is a three-dimensionally printed synthetic scaffold, composed of 90% by weight hydroxyapatite and 10% by weight poly(lactic-co-glycolic acid), with inherent bioactivity and porosity to allow for tissue integration. This study examines the capacity of Hyperelastic Bone for bone regeneration in a critical-size calvarial defect., Methods: Eight-millimeter calvarial defects in adult male Sprague-Dawley rats were treated with three-dimensionally printed Hyperelastic Bone, three-dimensionally printed Fluffy-poly(lactic-co-glycolic acid) without hydroxyapatite, autologous bone (positive control), or left untreated (negative control). Animals were euthanized at 8 or 12 weeks postoperatively and specimens were analyzed for new bone formation by cone beam computed tomography, micro-computed tomography, and histology., Results: The mineralized bone volume-to-total tissue volume fractions for the Hyperelastic Bone cohort at 8 and 12 weeks were 74.2 percent and 64.5 percent of positive control bone volume/total tissue, respectively (p = 0.04). Fluffy-poly(lactic-co-glycolic acid) demonstrated little bone formation, similar to the negative control. Histologic analysis of Hyperelastic Bone scaffolds revealed fibrous tissue at 8 weeks, and new bone formation surrounding the scaffold struts by 12 weeks., Conclusion: Findings from our study suggest that Hyperelastic Bone grafts are effective for bone regeneration, with significant potential for clinical translation.

Published

2019

7. Nanopatterning and Bioprinting in Orthopedic Surgery.

Author

Wodajo FM and Jakus AE

Subjects

Humans, Biocompatible Materials, Bioprinting methods, Orthopedic Procedures, Printing, Three-Dimensional, Tissue Engineering methods

Abstract

In part 1 of this article, the authors explore nanoscale modifications of the surfaces of biomaterials, which offer an exciting potential venue for the prevention of bacterial adhesion and growth. Despite advances in the design and manufacture of implants, infection remains an important and often devastating mode of failure. In part 2, additive technologies for tissue engineering, live cell printing (bioprinting), and tissue fabrication are briefly introduced. The similarities and differences between bioprinting and non-bio 3D-printing approaches and requirements are discussed, along with terminological definitions, current processes, requirements, and biomaterial and cell-type selection and sourcing., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2019

8. Voltaglue Bioadhesives Energized with Interdigitated 3D-Graphene Electrodes.

Author

Singh M, Nanda HS, O'Rorke RD, Jakus AE, Shah AH, Shah RN, Webster RD, and Steele TWJ

Subjects

Electrodes, Kinetics, Methane analogs & derivatives, Methane chemistry, Printing, Three-Dimensional, Graphite chemistry, Polyesters chemistry

Abstract

Soft tissue fixation of implant and bioelectrodes relies on mechanical means (e.g., sutures, staples, and screws), with associated complications of tissue perforation, scarring, and interfacial stress concentrations. Adhesive bioelectrodes address these shortcomings with voltage cured carbene-based bioadhesives, locally energized through graphene interdigitated electrodes. Electrorheometry and adhesion structure activity relationships are explored with respect to voltage and electrolyte on bioelectrodes synthesized from graphene 3D-printed onto resorbable polyester substrates. Adhesive leachates effects on in vitro metabolism and human-derived platelet-rich plasma response serves to qualitatively assess biological response. The voltage activated bioadhesives are found to have gelation times of 60 s or less with maximum shear storage modulus (G') of 3 kPa. Shear modulus mimics reported values for human soft tissues (0.1-10 kPa). The maximum adhesion strength achieved for the ≈50 mg bioelectrode films is 170 g cm -2 (17 kPa), which exceeds the force required for tethering of electrodes on dynamic soft tissues. The method provides the groundwork for implantable bio/electrodes that may be permanently incorporated into soft tissues, vis-à-vis graphene backscattering wireless electronics since all components are bioresorbable., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

9. Vascularization of Natural and Synthetic Bone Scaffolds.

Author

Liu X, Jakus AE, Kural M, Qian H, Engler A, Ghaedi M, Shah R, Steinbacher DM, and Niklason LE

Subjects

Bone Regeneration, Bone Transplantation methods, Bone and Bones blood supply, Cell Line, Composite Tissue Allografts cytology, Human Umbilical Vein Endothelial Cells, Humans, Printing, Three-Dimensional, Bone Substitutes chemistry, Bone and Bones chemistry, Endothelial Cells cytology, Myocytes, Smooth Muscle cytology, Neovascularization, Physiologic, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Vascularization of engineered bone tissue is critical for ensuring its survival after implantation. In vitro pre-vascularization of bone grafts with endothelial cells is a promising strategy to improve implant survival. In this study, we pre-cultured human smooth muscle cells (hSMCs) on bone scaffolds for 3 weeks followed by seeding of human umbilical vein endothelial cells (HUVECs), which produced a desirable environment for microvasculature formation. The sequential cell-seeding protocol was successfully applied to both natural (decellularized native bone, or DB) and synthetic (3D-printed Hyperelastic "Bone" scaffolds, or HB) scaffolds, demonstrating a comprehensive platform for developing natural and synthetic-based in vitro vascularized bone grafts. Using this sequential cell-seeding process, the HUVECs formed lumen structures throughout the DB scaffolds as well as vascular tissue bridging 3D-printed fibers within the HB. The pre-cultured hSMCs were essential for endothelial cell (EC) lumen formation within DB scaffolds, as well as for upregulating EC-specific gene expression of HUVECs grown on HB scaffolds. We further applied this co-culture protocol to DB scaffolds using a perfusion bioreactor, to overcome the limitations of diffusive mass transport into the interiors of the scaffolds. Compared with static culture, panoramic histological sections of DB scaffolds cultured in bioreactors showed improved cellular density, as well as a nominal increase in the number of lumen structures formed by ECs in the interior regions of the scaffolds. In conclusion, we have demonstrated that the sequential seeding of hSMCs and HUVECs can serve to generate early microvascular networks that could further support the in vitro tissue engineering of naturally or synthetically derived bone grafts and in both random (DB) and ordered (HB) pore networks. Combined with the preliminary bioreactor study, this process also shows potential to generate clinically sized, vascularized bone scaffolds for tissue and regenerative engineering.

Published

2018

10. NiTi-Nb micro-trusses fabricated via extrusion-based 3D-printing of powders and transient-liquid-phase sintering.

Author

Taylor SL, Ibeh AJ, Jakus AE, Shah RN, and Dunand DC

Subjects

Humans, Mesenchymal Stem Cells cytology, Materials Testing, Mesenchymal Stem Cells metabolism, Nickel chemistry, Nickel pharmacokinetics, Nickel pharmacology, Niobium chemistry, Niobium pharmacokinetics, Niobium pharmacology, Printing, Three-Dimensional, Titanium chemistry, Titanium pharmacokinetics, Titanium pharmacology, Trusses

Abstract

We present a novel additive manufacturing method for NiTi-Nb micro-trusses combining (i) extrusion-based 3D-printing of liquid inks containing NiTi and Nb powders, solvents, and a polymer binder into micro-trusses with 0/90° ABAB layers of parallel, ∼600 µm struts spaced 1 mm apart and (ii) subsequent heat-treatment to remove the binder and solvents, and then bond the NiTi powders using liquid phase sintering via the formation of a transient NiTi-Nb eutectic phase. We investigate the effects of Nb concentration (0, 1.5, 3.1, 6.7 at.% Nb) on the porosity, microstructure, and phase transformations of the printed NiTi-Nb micro-trusses. Micro-trusses with the highest Nb content exhibit long channels (from 3D-printing) and struts with smaller interconnected porosity (from partial sintering), resulting in overall porosities of ∼75% and low compressive stiffnesses of 1-1.6 GPa, similar to those of trabecular bone and in agreement with analytical and finite element modeling predictions. Diffusion of Nb into the NiTi particles from the bond regions results in a Ni-rich composition as the Nb replaces Ti atoms, leading to decreased martensite/austenite transformation temperatures. Adult human mesenchymal stem cells seeded on these micro-trusses showed excellent viability, proliferation, and extracellular matrix deposition over 14 days in culture., Statement of Significance: Near-equiatomic NiTi micro-trusses are attractive for biomedical applications such as stents, actuators, and bone implants because of their combination of biocompatibility, low compressive stiffness, high surface area, and shape-memory or superelasticity. Extrusion-based 3D-printing of NiTi powder-based inks into micro-trusses is feasible, but the subsequent sintering of the powders into dense struts is unachievable due to low diffusivity, large particle size, and low packing density of the NiTi powders. We present a solution, whereby Nb powders are added to the NiTi inks, thus forming during sintering a eutectic NiTi-Nb liquid phase which bonds the solid NiTi powders and improves densification of the struts. This study investigates the microstructure, porosity, phase transformation behavior, compressive stiffness, and cytocompatibility of these printed NiTi-Nb micro-trusses., (Copyright © 2018 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2018

11. Three-Dimensional Printing of Cytocompatible, Thermally Conductive Hexagonal Boron Nitride Nanocomposites.

Author

Guiney LM, Mansukhani ND, Jakus AE, Wallace SG, Shah RN, and Hersam MC

Subjects

Humans, Mesenchymal Stem Cells cytology, Nanocomposites ultrastructure, Nanotechnology methods, Surface Properties, Thermal Conductivity, Biocompatible Materials chemistry, Boron Compounds chemistry, Nanocomposites chemistry, Printing, Three-Dimensional

Abstract

Hexagonal boron nitride (hBN) is a thermally conductive yet electrically insulating two-dimensional layered nanomaterial that has attracted significant attention as a dielectric for high-performance electronics in addition to playing a central role in thermal management applications. Here, we report a high-content hBN-polymer nanocomposite ink, which can be 3D printed to form mechanically robust, self-supporting constructs. In particular, hBN is dispersed in poly(lactic- co-glycolic acid) and 3D printed at room temperature through an extrusion process to form complex architectures. These constructs can be 3D printed with a composition of up to 60% vol hBN (solids content) while maintaining high mechanical flexibility and stretchability. The presence of hBN within the matrix results in enhanced thermal conductivity (up to 2.1 W K -1 m -1 ) directly after 3D printing with minimal postprocessing steps, suggesting utility in thermal management applications. Furthermore, the constructs show high levels of cytocompatibility, making them suitable for use in the field of printed bioelectronics.

Published

2018

12. 3D-printing porosity: A new approach to creating elevated porosity materials and structures.

Author

Jakus AE, Geisendorfer NR, Lewis PL, and Shah RN

Subjects

Cell Adhesion drug effects, Cell Survival drug effects, Copper Sulfate chemistry, Humans, Hydrogels chemical synthesis, Hydrogels chemistry, Hydrogels pharmacology, Mesenchymal Stem Cells cytology, Porosity, Biocompatible Materials chemical synthesis, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Cell Proliferation drug effects, Materials Testing, Mesenchymal Stem Cells metabolism, Polylactic Acid-Polyglycolic Acid Copolymer chemistry, Polylactic Acid-Polyglycolic Acid Copolymer pharmacology, Printing, Three-Dimensional

Abstract

We introduce a new process that enables the ability to 3D-print high porosity materials and structures by combining the newly introduced 3D-Painting process with traditional salt-leaching. The synthesis and resulting properties of three 3D-printable inks comprised of varying volume ratios (25:75, 50:50, 70:30) of CuSO 4 salt and polylactide-co-glycolide (PLGA), as well as their as-printed and salt-leached counterparts, are discussed. The resulting materials are comprised entirely of PLGA (F-PLGA), but exhibit porosities proportional to the original CuSO 4 content. The three distinct F-PLGA materials exhibit average porosities of 66.6-94.4%, elastic moduli of 112.6-2.7 MPa, and absorbency of 195.7-742.2%. Studies with adult human mesenchymal stem cells (hMSCs) demonstrated that elevated porosity substantially promotes cell adhesion, viability, and proliferation. F-PLGA can also act as carriers for weak, naturally or synthetically-derived hydrogels. Finally, we show that this process can be extended to other materials including graphene, metals, and ceramics., Statement of Significance: Porosity plays an essential role in the performance and function of biomaterials, tissue engineering, and clinical medicine. For the same material chemistry, the level of porosity can dictate if it is cell, tissue, or organ friendly; with low porosity materials being far less favorable than high porosity materials. Despite its importance, it has been difficult to create three-dimensionally printed structures that are comprised of materials that have extremely high levels of internal porosity yet are surgically friendly (able to handle and utilize during surgical operations). In this work, we extend a new materials-centric approach to 3D-printing, 3D-Painting, to 3D-printing structures made almost entirely out of water-soluble salt. The structures are then washed in a specific way that not only extracts the salt but causes the structures to increase in size. With the salt removed, the resulting medical polymer structures are almost entirely porous and contain very little solid material, but the maintain their 3D-printed form and are highly compatible with adult human stem cells, are mechanically robust enough to use in surgical manipulations, and can be filled with and act as carriers for biologically active liquids and gels. We can also extend this process to three-dimensionally printing other porous materials, such as graphene, metals, and even ceramics., (Copyright © 2018 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2018

13. Applications of Three-Dimensional Printing in Orthopaedic Surgery.

Author

Anderson PA, Hsu W, Golish SR, Jakus AE, and Mihalko WM

Abstract

Orthopaedic surgeons should be aware of the variety of applications of three-dimensional printing, which range from rough-and-ready applications, such as rapid prototyping of implant designs with the use of polymers to the fabrication of patient-specific implants and custom implants with the use of the principles of metallurgy. The local manufacture of low-cost prosthetic devices in third-world nations is the best example of the potential application of three-dimensional printing. Orthopaedic surgeons should understand the multiple applications of three-dimensional printing, including prototyping of anatomy, implants, orthotics, patient-specific instrumentation, and implants that incorporate porous structures and accommodate complex anatomy, as well as the future of biologically active three-dimensional printing. It is helpful to be aware of the types of three-dimensional printing that are currently used in the clinical setting, those that are commercially available, and those under development.

Published

2018

14. Three-Dimensional Printing and Tissue Engineering in Orthopaedics.

Author

Jakus AE, Hsu W, Anderson PA, Golish SR, and Mihalko WM

Abstract

Additive manufacturing and three-dimensional printing technology may revolutionize tissue-engineering strategies. Many clinical needs, including multitissue regeneration, remain unmet among patients with orthopaedic conditions. Ongoing research efforts in three-dimensional printing, including cell-containing bioinks for bioprinting, have resulted in acellular and cellular biomaterials that may help regenerate or replace damaged or missing biologic tissues. Recent advances in additive manufacturing aid in the preservation of biologic activity, such as the retention of growth factors, which may affect the delivery of safe, cost-effective, and efficacious bone graft substitutes for orthopaedic patients.

Published

2018

15. Introduction to Additive Manufacturing and Three-Dimensional Printing in Orthopaedics.

Author

Jakus AE, Mihalko WM, Golish SR, Anderson PA, and Hsu W

Abstract

Additive manufacturing involves the construction of devices via the layer-by-layer deposition of materials. Additive manufacturing, which also is referred to as three-dimensional printing, is different from traditional machining, which involves the subtraction of material from a workpiece. Although traditional machining methods have been used in the field of manufacturing for decades, a recent rise in the commercial use of additive manufacturing has occurred in the field of orthopaedic surgery. Orthopaedic surgeons should understand the pertinent history of three-dimensional printing with regard to the field of manufacturing technology and the manner in which recent advances in additive manufacturing have allowed for new product designs with musculoskeletal applications. In addition, it is helpful to be aware of the regulatory aspects of additive manufacturing to ensure the safe and effective use of orthopaedic surgical devices created via three-dimensional printing.

Published

2018

16. "Tissue Papers" from Organ-Specific Decellularized Extracellular Matrices.

Author

Jakus AE, Laronda MM, Rashedi AS, Robinson CM, Lee C, Jordan SW, Orwig KE, Woodruff TK, and Shah RN

Abstract

Using an innovative, tissue-independent approach to decellularized tissue processing and biomaterial fabrication, the development of a series of "tissue papers" derived from native porcine tissues/organs (heart, kidney, liver, muscle), native bovine tissue/organ (ovary and uterus), and purified bovine Achilles tendon collagen as a control from decellularized extracellular matrix particle ink suspensions cast into molds is described. Each tissue paper type has distinct microstructural characteristics as well as physical and mechanical properties, is capable of absorbing up to 300% of its own weight in liquid, and remains mechanically robust ( E = 1-18 MPa) when hydrated; permitting it to be cut, rolled, folded, and sutured, as needed. In vitro characterization with human mesenchymal stem cells reveals that all tissue paper types support cell adhesion, viability, and proliferation over four weeks. Ovarian tissue papers support mouse ovarian follicle adhesion, viability, and health in vitro, as well as support, and maintain the viability and hormonal function of nonhuman primate and human follicle-containing, live ovarian cortical tissues ex vivo for eight weeks postmortem. "Tissue papers" can be further augmented with additional synthetic and natural biomaterials, as well as integrated with recently developed, advanced 3D-printable biomaterials, providing a versatile platform for future multi-biomaterial construct manufacturing., Competing Interests: Conflict of Interest The authors declare no conflict of interest.

Published

2017

17. Robust and Elastic Lunar and Martian Structures from 3D-Printed Regolith Inks.

Author

Jakus AE, Koube KD, Geisendorfer NR, and Shah RN

Abstract

Here, we present a comprehensive approach for creating robust, elastic, designer Lunar and Martian regolith simulant (LRS and MRS, respectively) architectures using ambient condition, extrusion-based 3D-printing of regolith simulant inks. The LRS and MRS powders are characterized by distinct, highly inhomogeneous morphologies and sizes, where LRS powder particles are highly irregular and jagged and MRS powder particles are rough, but primarily rounded. The inks are synthesized via simple mixing of evaporant, surfactant, and plasticizer solvents, polylactic-co-glycolic acid (30% by solids volume), and regolith simulant powders (70% by solids volume). Both LRS and MRS inks exhibit similar rheological and 3D-printing characteristics, and can be 3D-printed at linear deposition rates of 1-150 mm/s using 300 μm to 1.4 cm-diameter nozzles. The resulting LRS and MRS 3D-printed materials exhibit similar, but distinct internal and external microstructures and material porosity (~20-40%). These microstructures contribute to the rubber-like quasi-static and cyclic mechanical properties of both materials, with young's moduli ranging from 1.8 to 13.2 MPa and extension to failure exceeding 250% over a range of strain rates (10 -1 -10 2  min -1 ). Finally, we discuss the potential for LRS and MRS ink components to be reclaimed and recycled, as well as be synthesized in resource-limited, extraterrestrial environments.

Published

2017

18. Multi and mixed 3D-printing of graphene-hydroxyapatite hybrid materials for complex tissue engineering.

Author

Jakus AE and Shah RN

Subjects

Humans, Mesenchymal Stem Cells cytology, Porosity, Tissue Engineering methods, Durapatite chemistry, Graphite chemistry, Materials Testing, Mesenchymal Stem Cells metabolism, Printing, Three-Dimensional, Tissue Scaffolds chemistry

Abstract

With the emergence of three-dimensional (3D)-printing (3DP) as a vital tool in tissue engineering and medicine, there is an ever growing need to develop new biomaterials that can be 3D-printed and also emulate the compositional, structural, and functional complexities of human tissues and organs. In this work, we probe the 3D-printable biomaterials spectrum by combining two recently established functional 3D-printable particle-laden biomaterial inks: one that contains hydroxyapatite microspheres (hyperelastic bone, HB) and another that contains graphene nanoflakes (3D-graphene, 3DG). We demonstrate that not only can these distinct, osteogenic, and neurogenic inks be co-3D-printed to create complex, multimaterial constructs, but that composite inks of HB and 3DG can also be synthesized. Specifically, the printability, microstructural, mechanical, electrical, and biological properties of a hybrid material comprised of 1:1 HA:graphene by volume is investigated. The resulting HB-3DG hybrid exhibits mixed characteristics of the two distinct systems, while maintaining 3D-printability, electrical conductivity, and flexibility. In vitro assessment of HB-3DG using mesenchymal stem cells demonstrates the hybrid material supports cell viability and proliferation, as well as significantly upregulates both osteogenic and neurogenic gene expression over 14 days. This work ultimately demonstrates a significant step forward towards being able to 3D-print graded, multicompositional, and multifunctional constructs from hybrid inks for complex composite tissue engineering. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 105A: 274-283, 2017., (© 2016 Wiley Periodicals, Inc.)

Published

2017

19. Hyperelastic "bone": A highly versatile, growth factor-free, osteoregenerative, scalable, and surgically friendly biomaterial.

Author

Jakus AE, Rutz AL, Jordan SW, Kannan A, Mitchell SM, Yun C, Koube KD, Yoo SC, Whiteley HE, Richter CP, Galiano RD, Hsu WK, Stock SR, Hsu EL, and Shah RN

Subjects

Animals, Disease Models, Animal, Humans, Intercellular Signaling Peptides and Proteins pharmacology, Macaca, Materials Testing, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells drug effects, Mice, Printing, Three-Dimensional, Rats, Skull pathology, Spinal Fusion, Subcutaneous Tissue drug effects, Tissue Scaffolds chemistry, Biocompatible Materials pharmacology, Bone Regeneration drug effects, Bone and Bones physiology, Elasticity, Orthopedic Procedures

Abstract

Despite substantial attention given to the development of osteoregenerative biomaterials, severe deficiencies remain in current products. These limitations include an inability to adequately, rapidly, and reproducibly regenerate new bone; high costs and limited manufacturing capacity; and lack of surgical ease of handling. To address these shortcomings, we generated a new, synthetic osteoregenerative biomaterial, hyperelastic "bone" (HB). HB, which is composed of 90 weight % (wt %) hydroxyapatite and 10 wt % polycaprolactone or poly(lactic-co-glycolic acid), could be rapidly three-dimensionally (3D) printed (up to 275 cm(3)/hour) from room temperature extruded liquid inks. The resulting 3D-printed HB exhibited elastic mechanical properties (~32 to 67% strain to failure, ~4 to 11 MPa elastic modulus), was highly absorbent (50% material porosity), supported cell viability and proliferation, and induced osteogenic differentiation of bone marrow-derived human mesenchymal stem cells cultured in vitro over 4 weeks without any osteo-inducing factors in the medium. We evaluated HB in vivo in a mouse subcutaneous implant model for material biocompatibility (7 and 35 days), in a rat posterolateral spinal fusion model for new bone formation (8 weeks), and in a large, non-human primate calvarial defect case study (4 weeks). HB did not elicit a negative immune response, became vascularized, quickly integrated with surrounding tissues, and rapidly ossified and supported new bone growth without the need for added biological factors., (Copyright © 2016, American Association for the Advancement of Science.)

Published

2016

20. Functional Maturation of Induced Pluripotent Stem Cell Hepatocytes in Extracellular Matrix-A Comparative Analysis of Bioartificial Liver Microenvironments.

Author

Wang B, Jakus AE, Baptista PM, Soker S, Soto-Gutierrez A, Abecassis MM, Shah RN, and Wertheim JA

Subjects

Animals, Cell Culture Techniques methods, Extracellular Matrix metabolism, Humans, Immunohistochemistry, Male, Microscopy, Electron, Polyesters, Rats, Rats, Sprague-Dawley, Reverse Transcriptase Polymerase Chain Reaction, Hepatocytes cytology, Induced Pluripotent Stem Cells cytology, Liver, Artificial, Tissue Engineering methods, Tissue Scaffolds

Abstract

Unlabelled: : Induced pluripotent stem cells (iPSCs) are new diagnostic and potentially therapeutic tools to model disease and assess the toxicity of pharmaceutical medications. A common limitation of cell lineages derived from iPSCs is a blunted phenotype compared with fully developed, endogenous cells. We examined the influence of novel three-dimensional bioartificial microenvironments on function and maturation of hepatocyte-like cells differentiated from iPSCs and grown within an acellular, liver-derived extracellular matrix (ECM) scaffold. In parallel, we also compared a bioplotted poly-l-lactic acid (PLLA) scaffold that allows for cell growth in three dimensions and formation of cell-cell contacts but is infused with type I collagen (PLLA-collagen scaffold) alone as a "deconstructed" control scaffold with narrowed biological diversity. iPSC-derived hepatocytes cultured within both scaffolds remained viable, became polarized, and formed bile canaliculi-like structures; however, cells grown within ECM scaffolds had significantly higher P450 (CYP2C9, CYP3A4, CYP1A2) mRNA levels and metabolic enzyme activity compared with iPSC hepatocytes grown in either bioplotted PLLA collagen or Matrigel sandwich control culture. Additionally, the rate of albumin synthesis approached the level of primary cryopreserved hepatocytes with lower transcription of fetal-specific genes, α-fetoprotein and CYP3A7, compared with either PLLA-collagen scaffolds or sandwich culture. These studies show that two acellular, three-dimensional culture systems increase the function of iPSC-derived hepatocytes. However, scaffolds derived from ECM alone induced further hepatocyte maturation compared with bioplotted PLLA-collagen scaffolds. This effect is likely mediated by the complex composition of ECM scaffolds in contrast to bioplotted scaffolds, suggesting their utility for in vitro hepatocyte assays or drug discovery., Significance: Through the use of novel technology to develop three-dimensional (3D) scaffolds, the present study demonstrated that hepatocyte-like cells derived via induced pluripotent stem cell (iPSC) technology mature on 3D extracellular matrix scaffolds as a result of 3D matrix structure and scaffold biology. The result is an improved hepatic phenotype with increased synthetic and catalytic potency, an improvement on the blunted phenotype of iPSC-derived hepatocytes, a critical limitation of iPSC technology. These findings provide insight into the influence of 3D microenvironments on the viability, proliferation, and function of iPSC hepatocytes to yield a more mature population of cells for cell toxicity studies and disease modeling., (©AlphaMed Press.)

Published

2016

21. Advancing the field of 3D biomaterial printing.

Author

Jakus AE, Rutz AL, and Shah RN

Subjects

Equipment Design, Nanoparticles ultrastructure, Biocompatible Materials chemical synthesis, Nanoparticles chemistry, Printing, Three-Dimensional trends, Tissue Engineering instrumentation, Tissue Engineering trends, Tissue Scaffolds

Abstract

3D biomaterial printing has emerged as a potentially revolutionary technology, promising to transform both research and medical therapeutics. Although there has been recent progress in the field, on-demand fabrication of functional and transplantable tissues and organs is still a distant reality. To advance to this point, there are two major technical challenges that must be overcome. The first is expanding upon the limited variety of available 3D printable biomaterials (biomaterial inks), which currently do not adequately represent the physical, chemical, and biological complexity and diversity of tissues and organs within the human body. Newly developed biomaterial inks and the resulting 3D printed constructs must meet numerous interdependent requirements, including those that lead to optimal printing, structural, and biological outcomes. The second challenge is developing and implementing comprehensive biomaterial ink and printed structure characterization combined with in vitro and in vivo tissue- and organ-specific evaluation. This perspective outlines considerations for addressing these technical hurdles that, once overcome, will facilitate rapid advancement of 3D biomaterial printing as an indispensable tool for both investigating complex tissue and organ morphogenesis and for developing functional devices for a variety of diagnostic and regenerative medicine applications.

Published

2016

22. Initiation of puberty in mice following decellularized ovary transplant.

Author

Laronda MM, Jakus AE, Whelan KA, Wertheim JA, Shah RN, and Woodruff TK

Subjects

Adolescent, Adult, Animals, Biopsy, Cattle, Cell Line, Tumor, Child, Estradiol pharmacology, Extracellular Matrix metabolism, Female, Humans, Mice, Middle Aged, Ovarian Follicle drug effects, Ovarian Follicle pathology, Ovary drug effects, Ovary ultrastructure, Precursor Cell Lymphoblastic Leukemia-Lymphoma pathology, Tissue Scaffolds chemistry, Transcription Factors metabolism, Ovary cytology, Ovary transplantation, Sexual Maturation drug effects

Abstract

Clinical interventions to preserve fertility and restore hormone levels in female patients with therapy-induced ovarian failure are insufficient, particularly for pediatric cancer patients. Laparoscopic isolation of cortical ovarian tissue followed by cryopreservation with subsequent autotransplantation has temporarily restored fertility in at least 27 women who survived cancer, and aided in pubertal transition for one pediatric patient. However, reintroducing cancer cells through ovarian transplantation has been a major concern. Decellularization is a process of removing cellular material, while maintaining the organ skeleton of extracellular matrices (ECM). The ECM that remains could be stripped of cancer cells and reseeded with healthy ovarian cells. We tested whether a decellularized ovarian scaffold could be created, recellularized and transplanted to initiate puberty in mice. Bovine and human ovaries were decellularized, and the ovarian skeleton microstructures were characterized. Primary ovarian cells seeded onto decellularized scaffolds produced estradiol in vitro. Moreover, the recellularized grafts initiated puberty in mice that had been ovariectomized, providing data that could be used to drive future human transplants and have broader implications on the bioengineering of other organs with endocrine function., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

23. A multimaterial bioink method for 3D printing tunable, cell-compatible hydrogels.

Author

Rutz AL, Hyland KE, Jakus AE, Burghardt WR, and Shah RN

Subjects

Bioprinting instrumentation, Bioprinting methods, Cell Survival, Fibrinogen chemistry, Gelatin chemistry, Humans, Materials Testing, Mesenchymal Stem Cells physiology, Polyethylene Glycols chemistry, Rheology, Tissue Scaffolds chemistry, Biocompatible Materials, Hydrogels chemical synthesis, Hydrogels chemistry, Ink, Printing, Three-Dimensional instrumentation, Tissue Engineering instrumentation, Tissue Engineering methods

Abstract

A multimaterial bio-ink method using polyethylene glycol crosslinking is presented for expanding the biomaterial palette required for 3D bioprinting of more mimetic and customizable tissue and organ constructs. Lightly crosslinked, soft hydrogels are produced from precursor solutions of various materials and 3D printed. Rheological and biological characterizations are presented, and the promise of this new bio-ink synthesis strategy is discussed., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

24. Three-dimensional printing of high-content graphene scaffolds for electronic and biomedical applications.

Author

Jakus AE, Secor EB, Rutz AL, Jordan SW, Hersam MC, and Shah RN

Subjects

Animals, Cell Adhesion drug effects, Cell Proliferation drug effects, Cell Survival drug effects, Female, Humans, Ink, Mechanical Phenomena, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells drug effects, Mice, Models, Molecular, Molecular Conformation, Neurogenesis drug effects, Neurons cytology, Neurons drug effects, Polyglactin 910 chemistry, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Electric Conductivity, Graphite chemistry, Graphite pharmacology, Printing, Three-Dimensional, Tissue Scaffolds chemistry

Abstract

The exceptional properties of graphene enable applications in electronics, optoelectronics, energy storage, and structural composites. Here we demonstrate a 3D printable graphene (3DG) composite consisting of majority graphene and minority polylactide-co-glycolide, a biocompatible elastomer, 3D-printed from a liquid ink. This ink can be utilized under ambient conditions via extrusion-based 3D printing to create graphene structures with features as small as 100 μm composed of as few as two layers (<300 μm thick object) or many hundreds of layers (>10 cm thick object). The resulting 3DG material is mechanically robust and flexible while retaining electrical conductivities greater than 800 S/m, an order of magnitude increase over previously reported 3D-printed carbon materials. In vitro experiments in simple growth medium, in the absence of neurogenic stimuli, reveal that 3DG supports human mesenchymal stem cell (hMSC) adhesion, viability, proliferation, and neurogenic differentiation with significant upregulation of glial and neuronal genes. This coincides with hMSCs adopting highly elongated morphologies with features similar to axons and presynaptic terminals. In vivo experiments indicate that 3DG has promising biocompatibility over the course of at least 30 days. Surgical tests using a human cadaver nerve model also illustrate that 3DG has exceptional handling characteristics and can be intraoperatively manipulated and applied to fine surgical procedures. With this unique set of properties, combined with ease of fabrication, 3DG could be applied toward the design and fabrication of a wide range of functional electronic, biological, and bioelectronic medical and nonmedical devices.

Published

2015

25. In situ forming collagen-hyaluronic acid membrane structures: mechanism of self-assembly and applications in regenerative medicine.

Author

Chung EJ, Jakus AE, and Shah RN

Subjects

Animals, Cattle, Cell Proliferation drug effects, Coated Materials, Biocompatible pharmacology, Collagen ultrastructure, Durapatite chemistry, Humans, Hydrogen-Ion Concentration, Materials Testing, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells drug effects, Serum Albumin, Bovine metabolism, Solutions, Static Electricity, Tendons drug effects, Transplantation, Homologous, Collagen chemistry, Hyaluronic Acid chemistry, Membranes, Artificial, Regenerative Medicine methods

Abstract

Bioactive, in situ forming materials have the potential to complement minimally invasive surgical procedures and enhance tissue healing. For such biomaterials to be adopted in the clinic, they must be cost-effective, easily handled by the surgeon and have a history of biocompatibility. To this end, we report a novel and facile self-assembling strategy to create membranes and encapsulating structures using collagen and hyaluronic acid (HA). Unlike membranes built by layer-by-layer deposition of oppositely charged biomolecules, the collagen-HA membranes described here form a diffusion barrier upon electrostatic interaction of the oppositely charged biomolecules, which is further driven by osmotic pressure imbalances. The resulting membranes have a nanofibrous architecture, a thicknesses of 130 μm and a tensile modulus (0.59±0.06 MPa) that can increase 7-fold using carbodiimide chemistry (4.42±1.46 MPa). Collagen-HA membranes support mesenchymal stem cell proliferation and have a slow and steady protein release profile (7% at day 28), offering opportunities for targeted tissue regeneration. We demonstrate the capacity to encapsulate cells by injecting HA into the collagen solution, and enhance allograft and implant biocompatibility through a coating technique. This study describes a novel mechanism of collagen-HA membrane formation and provides the groundwork to apply these membranes in a variety of tissue engineering applications., (Copyright © 2012 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2013