Prefabrication technique by preserving a muscular pedicle from masseter muscle as an in vivo bioreactor for reconstruction of mandibular critical‐sized bone defects in canine models

Nokhbatolfoghahaei, Hanieh; Bastami, Farshid; Farzad‐Mohajeri, Saeed; Rad, Maryam Rezai; Dehghan, Mohammad Mehdi; Bohlouli, Mahboubeh; Farajpour, Hekmat; Nadjmi, Nasser; Khojasteh, Arash

doi:10.1002/jbm.b.35028

Cited by 14 publications

(9 citation statements)

References 43 publications

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“…A similar improvement was obtained by Nokhbatolfoghahaei et al and Park et al, who seeded MSCs and TMSCs on PCL/ β ‐TCP scaffolds, showing quantitatively the improvement in bone regeneration (15.430% ± 0.547% and 5.813% ± 1.345%), compared to scaffolds alone or scaffolds combined only with growth factors. [ 39,40 ] Finally, Temple et al and Roskies et al have proven the efficacy of the seeding of ACSCs aggregates on both PCL (Figure 8C) and PEKK (Figure 8D) scaffolds, showing a higher cell infiltration in the seeded scaffolds after 7 days of in vivo implantation. [ 48,49 ]…”

Section: Cell Therapymentioning

confidence: 98%

“…[ 42 ] Nokhbatolfoghahaei et al have also tested β ‐TCP scaffolds in several conditions in a canine animal model, and always reported higher histomorphometry values of NB in the presence of rh‐BMP‐2 (NB = 48.443 ± 0.250%). [ 39 ] On the other hand, despite reporting a modest trend of bone formation for PCL/ β ‐TCP scaffolds soaked into a BMP‐2/collagen solution (BV/TV ≈ 13%), results of Lee et al lacked statistical significance when compared to the control group (PCL/ β ‐TCP alone). [ 36 ] Similar outcomes were reported in another PCL/ β ‐TCP scaffold study, where intra‐scaffold injections of a rhBMP‐2 and bdECM bioink improved bone‐to‐implant contact ratio (BIC) (BIC = 51.29 ± 14.64%), but NB was again not significantly ameliorated.…”

Section: Bioactive Molecules For Mandibular Regenerationmentioning

confidence: 99%

“…[35,38] Depending on the structure (e.g., 0-90°pattern, kagome, or 0-45°or 0-30°pattern) and the presence of ceramic elements, PCL scaffolds displayed compressive strength values between 10 and 30 MPa and E flex between 70 and 170 MPa. [36,39,40,76] These values are at least one order of magnitude lower than cancellous bone and two orders of magnitude lower than cortical bone. In mandibular bone reconstruction applications, mechanical strength and load-bearing capacity are crucial factors, as the mandible experiences high loads during its lifespan.…”

Section: Scaffold Structure and Designmentioning

confidence: 99%

“…Significantly greater rate of NB (NB = 48.443 ± 0.250%) was obtained in vivo but, despite all, capillary formation within the constructs could not be proven by histological analysis (Figure 7C). [39] Finally, Konopnicki et al hypothesized that vessels penetration in 𝛽-TCP/PCL scaffolds seeded with porcine bone marrow progenitor cells (pBMPCs) was improved by early implanting the constructs in a critical-size mandibular defect (i.e., before the 14th days of in vitro culture). [34] The problem of scaffold vascularization in the context of mandibular BTE remains the narrowest bottleneck that is currently limiting translation of academic research into clinic.…”

Section: Vascularization Strategies For Mandibular Regenerationmentioning

confidence: 99%

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Regeneration of Critical‐Sized Mandibular Defects Using 3D‐Printed Composite Scaffolds: A Quantitative Evaluation of New Bone Formation in In Vivo Studies

Dalfino

Savadori

Piazzoni

et al. 2023

Adv Healthcare Materials

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Mandibular tissue engineering aims to develop synthetic substitutes for the regeneration of critical size defects (CSD) caused by a variety of events, including tumor surgery and post‐traumatic resections. Currently, the gold standard clinical treatment of mandibular resections (i.e., autologous fibular flap) has many drawbacks, driving research efforts toward scaffold design and fabrication by additive manufacturing (AM) techniques. Once implanted, the scaffold acts as a support for native tissue and facilitates processes that contribute to its regeneration, such as cells infiltration, matrix deposition and angiogenesis. However, to fulfil these functions, scaffolds must provide bioactivity by mimicking natural properties of the mandible in terms of structure, composition and mechanical behavior. This review aims to present the state of the art of scaffolds made with AM techniques that are specifically employed in mandibular tissue engineering applications. Biomaterials chemical composition and scaffold structural properties are deeply discussed, along with strategies to promote osteogenesis (i.e., delivery of biomolecules, incorporation of stem cells, and approaches to induce vascularization in the constructs). Finally, a comparison of in vivo studies is made by taking into consideration the amount of new bone formation (NB), the CSD dimensions, and the animal model.

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Section: Cell Therapymentioning

confidence: 98%

Section: Bioactive Molecules For Mandibular Regenerationmentioning

confidence: 99%

Section: Scaffold Structure and Designmentioning

confidence: 99%

Section: Vascularization Strategies For Mandibular Regenerationmentioning

confidence: 99%

See 2 more Smart Citations

Regeneration of Critical‐Sized Mandibular Defects Using 3D‐Printed Composite Scaffolds: A Quantitative Evaluation of New Bone Formation in In Vivo Studies

Dalfino

Savadori

Piazzoni

et al. 2023

Adv Healthcare Materials

View full text Add to dashboard Cite

show abstract

“…To address these obstacles, a novel approach involves the in vivo implantation of a scaffold into an ectopic site such as skin or muscle, termed an in vivo bioreactor (IVB), with subsequent transfer of the newly vascularized scaffold into the bony site of interest [ 58 , 59 , 60 , 61 , 62 ]. To date, many preclinical studies have demonstrated robust bone healing responses using the IVB method [ 63 , 64 , 65 , 66 ]. The majority of IVB use in humans involves grafting periosteum along with its vascular supply to the site of interest [ 67 , 68 , 69 , 70 ], but actual prefabrication techniques involving ectopic maturation of a scaffold with subsequent transfer to the site of interest are rare in clinical studies.…”

Section: Future Directions For Addressing Bone Lossmentioning

confidence: 99%

3D-Printing for Critical Sized Bone Defects: Current Concepts and Future Directions

et al. 2022

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The management and definitive treatment of segmental bone defects in the setting of acute trauma, fracture non-union, revision joint arthroplasty, and tumor surgery are challenging clinical problems with no consistently satisfactory solution. Orthopaedic surgeons are developing novel strategies to treat these problems, including three-dimensional (3D) printing combined with growth factors and/or cells. This article reviews the current strategies for management of segmental bone loss in orthopaedic surgery, including graft selection, bone graft substitutes, and operative techniques. Furthermore, we highlight 3D printing as a technology that may serve a major role in the management of segmental defects. The optimization of a 3D-printed scaffold design through printing technique, material selection, and scaffold geometry, as well as biologic additives to enhance bone regeneration and incorporation could change the treatment paradigm for these difficult bone repair problems.

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Improving material properties of a poloxamer P407 hydrogel‐based hydroxyapatite bone substitute material by adding silica—A comparative in vivo study

Kämmerer,

Heimes,

Zaage

et al. 2024

J Biomed Mater Res

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The structure and handling properties of a P407 hydrogel‐based bone substitute material (BSM) might be affected by different poloxamer P407 and silicon dioxide (SiO2) concentrations. The study aimed to compare the mechanical properties and biological parameters (bone remodeling, BSM degradation) of a hydroxyapatite: silica (HA)‐based BSM with various P407 hydrogels in vitro and in an in vivo rat model. Rheological analyses for mechanical properties were performed on one BSM with an SiO2‐enriched hydrogel (SPH25) as well on two BSMs with unaltered hydrogels in different gel concentrations (PH25 and PH30). Furthermore, the solubility of all BSMs were tested. In addition, 30 male Wistar rats underwent surgical creation of a well‐defined bone defect in the tibia. Defects were filled randomly with PH30 (n = 15) or SPH25 (n = 15). Animals were sacrificed after 12 (n = 5 each), 21 (n = 5 each), and 63 days (n = 5 each). Histological evaluation and histomorphometrical quantification of new bone formation (NB;%), residual BSM (rBSM;%), and soft tissue (ST;%) was conducted. Rheological tests showed an increased viscosity and lower solubility of SPH when compared with the other hydrogels. Histomorphometric analyses in cancellous bone showed a decrease of ST in PH30 (p = .003) and an increase of NB (PH30: p = .001; SPH: p = .014) over time. A comparison of both BSMs revealed no significant differences. The addition of SiO2 to a P407 hydrogel‐based hydroxyapatite BSM improves its mechanical stability (viscosity, solubility) while showing similar in vivo healing properties compared to PH30. Additionally, the SiO2‐enrichment allows a reduction of poloxamer ratio in the hydrogel without impairing the material properties.

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Prefabrication technique by preserving a muscular pedicle from masseter muscle as an in vivo bioreactor for reconstruction of mandibular critical‐sized bone defects in canine models

Cited by 14 publications

References 43 publications

Regeneration of Critical‐Sized Mandibular Defects Using 3D‐Printed Composite Scaffolds: A Quantitative Evaluation of New Bone Formation in In Vivo Studies

Regeneration of Critical‐Sized Mandibular Defects Using 3D‐Printed Composite Scaffolds: A Quantitative Evaluation of New Bone Formation in In Vivo Studies

3D-Printing for Critical Sized Bone Defects: Current Concepts and Future Directions

Improving material properties of a poloxamer P407 hydrogel‐based hydroxyapatite bone substitute material by adding silica—A comparative in vivo study

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