Your search keyword '"Maximilian M. Saller"' showing total 17 results

1. RNA-seq unravels distinct expression profiles of keloids and Dupuytren's disease

Author

Marcus Stocks, Annika S. Walter, Elif Akova, Gerd Gauglitz, Attila Aszodi, Wolfgang Boecker, Maximilian M. Saller, and Elias Volkmer

Subjects

Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Keloid scars and Dupuytren's disease are two common, chronic, and incurable fibroproliferative disorders that, among other shared clinical features, may induce joint contractures. We employed bulk RNA sequencing to discern potential shared gene expression patterns and underlying pathological pathways between these two conditions. Our aim was to uncover potential molecular targets that could pave the way for novel therapeutic strategies. Differentially expressed genes (DEGs) were functionally annotated using Gene Ontology (GO) terms and the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways with the Database for Annotation, Visualization, and Integrated Discovery (DAVID). The protein-protein-interaction (PPI) networks were constructed by using the Search Tool for the Retrieval of Interacting Genes (STRING) and Cytoscape. The Molecular Complex Detection (MCODE) plugin was used for downstream analysis of the PPI networks. A total of 1922 DEGs were identified within Dupuytren's and keloid samples, yet no overlapping gene expression profiles were detected. Significantly enriched GO terms were related to skin development and tendon formation in keloid scars and Dupuytren's disease, respectively. The PPI network analysis revealed 10 genes and the module analysis provided six protein networks, which might play an integral part in disease development. These genes, including CDH1, ERBB2, CASP3 and RPS27A, may serve as new targets for future research to develop biomarkers and/or therapeutic agents.

Published

2024

2. The influence of vitamin D on handgrip strength in elderly trauma patients

Author

Tamara Ostermeier, Leon Faust, Adrian Cavalcanti-Kußmaul, Christian Kammerlander, Matthias Knobe, Wolfgang Böcker, Maximilian M. Saller, Carl Neuerburg, and Alexander M. Keppler

Subjects

Handgrip strength, Dynamometer, Vitamin D, 25-OH vitamin D concentration, Orthogeriatric, Trauma patients, Medicine

Abstract

Abstract Background and objectives The treatment of elderly patients is an increasing challenge and the long-term sequelae often affect activities of daily living and quality of life in those patients. Handgrip strength (HGS) appears as a promising value to predict the outcome after trauma in elderly patients and to assess the overall muscle strength. Besides the possible role of psychological and hormonal factors, vitamin D may have a positive influence. Furthermore, some data suggest that Vitamin D is beneficial regarding muscle strength and possibly prevents further falls and injuries in orthogeriatric patients. The purpose of this study was to identify if Vitamin D is an influencing factor for HGSin elderly trauma patients. Materials and methods 94 elderly patients in a Level I Trauma Center aged 60 years or older were prospectively enrolled and HGS as well as serum 25-OH Vitamin D concentration (VDC) were measured. In addition, the standardized questionnaires Barthel Index (BI), Parker Mobility Score (PMS), Short Physical Performance Battery (SPPB), Strength, Assistance with walking, Rise from a chair, Climb stairs and Falls (SARC-F) and European Quality of Life 5 Dimensions 5 Levels Questionnaire (EQ-5D-5L), were used to record mental health status and demographic data. Results HGS is mainly related to age and sex in elderly trauma patients. HGS was higher in men (meanmale = 27.31 kg (± 8.11), meanfemale = 15.62 kg (± 5.63), p

Published

2023

3. Bone defect reconstruction with a novel biomaterial containing calcium phosphate and aluminum oxide reinforcement

Author

Alexander M. Keppler, Maximilian M. Saller, Alberton Paolo, Westphal Ines, Heidenau Frank, Schönitzer Veronika, Böcker Wolfgang, Kammerlander Christian, Schieker Matthias, Aszodi Attila, and Neuerburg Carl

Subjects

Orthopedic surgery, RD701-811, Diseases of the musculoskeletal system, RC925-935

Abstract

Abstract Background Reconstruction of metaphyseal fractures represents a clinical challenge for orthopedic surgeons. Especially in osteoporotic bone, these fractures are frequently accompanied by osseous substance defects. In order to ensure rapid mobilization of patients, high stability requirements must be met by osteosynthesis. Various bone graft materials have been introduced in the past, such as autologous bone or exogenous bone substitute materials. These are used as bone void fillers or as augmentation techniques to ensure safe fixation of osteosynthesis. New calcium phosphate-based bone void-filling materials could be a promising alternative to autologous bone or to the currently and widely used polymethylmethacrylate (PMMA)-based cement. The aim of this study was to evaluate a novel paste-like bone void filler in vivo and in vitro with regard to biocompatibility and osteoconductivity. Methods In addition to in vitro testing of cell compatibility using pre-osteoblasts (MC3T3-E1), 35 Wistar rats were treated in vivo with implantation of various material mixtures based on calcium phosphate and aluminum oxide reinforcement in a metaphyseal drill hole defect. After 4 weeks, an examination by micro-computed tomography (μCT) and histology was performed. Results The in vitro analysis showed good biocompatibility with a high cell survival of osteoblasts. In the in vivo experiments, a significantly higher bone ingrowth compared to the empty defect was shown by μCT and histological analysis. Here, the group receiving material reinforced with aluminum oxide (Al2O3) showed a bone volume/tissue volume (BV/TV) of 89.19% compared to a BV/TV of 83.14% for the empty defect (p = 0.0013). In the group treated with a polysaccharide matrix, no increase in BV/TV was observed given a mean ratio of 80.14%. Scoring of histological sections did not reveal a significant difference between CaP and CaP that was substituted with Al2O3. Conclusion The results of this study show an encouraging first step towards the development of new pasty, bone void-filling materials. We demonstrated that a new paste-like bone-filling material, based on calcium phosphate granulates and aluminum oxide to provide strength, exhibits good biocompatibility and osteoconductivity. Further biomechanical test in an osteoporotic animal model will have to be performed, to prove feasibility in metaphyseal defects.

Published

2020

4. Dental and Orthopaedic Implant Loosening: Overlap in Gene Expression Regulation

Author

Sabine Schluessel, Eliza S. Hartmann, Miriam I. Koehler, Felicitas Beck, Julia I. Redeker, Maximilian M. Saller, Elif Akova, Stefan Krebs, Boris M. Holzapfel, and Susanne Mayer-Wagner

Subjects

dental and orthopaedic implant failure, osteoclastogenic regulation, periprosthetic tissue, immune reaction, RNA-sequencing, immune osteoclastic cells, Immunologic diseases. Allergy, RC581-607

Abstract

ObjectivesEndoprosthetic loosening still plays a major role in orthopaedic and dental surgery and includes various cellular immune processes within peri-implant tissues. Although the dental and orthopaedic processes vary in certain parts, the clinical question arises whether there are common immune regulators of implant loosening. Analyzing the key gene expressions common to both processes reveals the mechanisms of osteoclastogenesis within periprosthetic tissues of orthopaedic and dental origin.MethodsDonor peripheral blood mononuclear cells (PBMCs) and intraoperatively obtained periprosthetic fibroblast-like cells (PPFs) were (co-)cultured with [± macrophage-colony stimulating factor (MCSF) and Receptor Activator of NF-κB ligand (RANKL)] in transwell and monolayer culture systems and examined for osteoclastogenic regulations [MCSF, RANKL, osteoprotegerin (OPG), and tumor necrosis factor alpha (TNFα)] as well as the ability of bone resorption. Sequencing analysis compared dental and orthopaedic (co-)cultures.ResultsMonolayer co-cultures of both origins expressed high levels of OPG, resulting in inhibition of osteolysis shown by resorption assay on dentin. The high OPG-expression, low RANKL/OPG ratios and a resulting inhibition of osteolysis were displayed by dental and orthopaedic PPFs in monolayer even in the presence of MCSF and RANKL, acting as osteoprotective and immunoregulatory cells. The osteoprotective function was only observed in monolayer cultures of dental and orthopaedic periprosthetic cells and downregulated in the transwell system. In transwell co-cultures of PBMCs/PPFs profound changes of gene expression, with a significant decrease of OPG (20-fold dental versus 100 fold orthopaedic), were identified. Within transwell cultures, which offer more in vivo like conditions, RANKL/OPG ratios displayed similar high levels to the original periprosthetic tissue. For dental and orthopaedic implant loosening, overlapping findings in principal component and heatmap analysis were identified.ConclusionsThus, periprosthetic osteoclastogenesis may be a correlating immune process in orthopaedic and dental implant failure leading to comparable reactions with regard to osteoclast formation. The transwell cultures system may provide an in vivo like model for the exploration of orthopaedic and dental implant loosening.

Published

2022

5. Growth factor-mediated augmentation of long bones: evaluation of a BMP-7 loaded thermoresponsive hydrogel in a murine femoral intramedullary injection model

Author

Carl Neuerburg, Lena M. Mittlmeier, Alexander M. Keppler, Ines Westphal, Änne Glass, Maximilian M. Saller, Philipp K. E. Herlyn, Heiko Richter, Wolfgang Böcker, Matthias Schieker, Attila Aszodi, and Dagmar-C. Fischer

Subjects

Osteoporosis, Murine femoral intramedullary injection model, Bone morphogenetic protein 7 (BMP-7), BDI-hydrogel, Orthopedic surgery, RD701-811, Diseases of the musculoskeletal system, RC925-935

Abstract

Abstract Background Due to our aging population, an increase in proximal femur fractures can be expected, which is associated with impaired activities of daily living and a high risk of mortality. These patients are also at a high risk to suffer a secondary osteoporosis-related fracture on the contralateral hip. In this context, growth factors could open the field for regenerative approaches, as it is known that, i.e., the growth factor BMP-7 (bone morphogenetic protein 7) is a potent stimulator of osteogenesis. Local prophylactic augmentation of the proximal femur with a BMP-7 loaded thermoresponsive hydrogel during index surgery of an osteoporotic fracture could be suitable to reduce the risk of further osteoporosis-associated secondary fractures. The present study therefore aims to test the hypothesis if a BMP-7 augmented hydrogel is an applicable carrier for the augmentation of non-fractured proximal femurs. Furthermore, it needs to be shown that the minimally invasive injection of a hydrogel into the mouse femur is technically feasible. Methods In this study, male C57BL/6 mice (n = 36) received a unilateral femoral intramedullary injection of either 100 μl saline, 100 μl 1,4 Butan-Diisocyanat (BDI)-hydrogel, or 100 μl hydrogel loaded with 1 μg of bone morphogenetic protein 7. Mice were sacrificed 4 and 12 weeks later. The femora were submitted to high-resolution X-ray tomography and subsequent histological examination. Results Analysis of normalized CtBMD (Cortical bone mineral density) as obtained by X-ray micro-computed tomography analysis revealed significant differences depending on the duration of treatment (4 vs 12 weeks; p

Published

2019

6. Fusion of Normoxic- and Hypoxic-Preconditioned Myoblasts Leads to Increased Hypertrophy

Author

Tamara Pircher, Henning Wackerhage, Elif Akova, Wolfgang Böcker, Attila Aszodi, and Maximilian M. Saller

Subjects

C2C12, myoblasts, myotube, fusion, myogenic differentiation, hypoxia, Cytology, QH573-671

Abstract

Injuries, high altitude, and endurance exercise lead to hypoxic conditions in skeletal muscle and sometimes to hypoxia-induced local tissue damage. Thus, regenerative myoblasts/satellite cells are exposed to different levels and durations of partial oxygen pressure depending on the spatial distance from the blood vessels. To date, it is unclear how hypoxia affects myoblasts proliferation, differentiation, and particularly fusion with normoxic myoblasts. To study this, we investigated how 21% and 2% oxygen affects C2C12 myoblast morphology, proliferation, and myogenic differentiation and evaluated the fusion of normoxic- or hypoxic-preconditioned C2C12 cells in 21% or 2% oxygen in vitro. Out data show that the long-term hypoxic culture condition does not affect the proliferation of C2C12 cells but leads to rounder cells and reduced myotube formation when compared with myoblasts exposed to normoxia. However, when normoxic- and hypoxic-preconditioned myoblasts were differentiated together, the resultant myotubes were significantly larger than the control myotubes. Whole transcriptome sequencing analysis revealed several novel candidate genes that are differentially regulated during the differentiation under normoxia and hypoxia in mixed culture conditions and may thus be involved in the increase in myotube size. Taken together, oxygen-dependent adaption and interaction of myoblasts may represent a novel approach for the development of innovative therapeutic targets.

Published

2022

7. Correction to: Bone defect reconstruction with a novel biomaterial containing calcium phosphate and aluminum oxide reinforcement

Author

Alexander M. Keppler, Maximilian M. Saller, Paolo Alberton, Ines Westphal, Frank Heidenau, Veronika Schönitzer, Wolfgang Böcker, Christian Kammerlander, Matthias Schieker, Attila Aszodi, and Carl Neuerburg

Subjects

Orthopedic surgery, RD701-811, Diseases of the musculoskeletal system, RC925-935

Abstract

An amendment to this paper has been published and can be accessed via the original article.

Published

2020

8. Effect of shape and size of supraspinatus tears on rotator cuff strain distribution: an in vitro study

Author

Inês Santos, Lieselotte Pichler, Maximilian M. Saller, Christoph Thorwächter, Julia Gertrud Müller, Hannes Traxler, Matthias F. Pietschmann, Mark Tauber, and Peter E. Müller

Subjects

Orthopedics and Sports Medicine, Surgery, General Medicine

Abstract

The impact of size and shape of a supraspinatus tear on the strain of the intact rotator cuff and the kinematics of the shoulder is still unknown. This, however, can be relevant to the decision-making of whether surgical reconstruction is required to prevent an increase in tendon defect. In this study, the effect of tear width and shape on rotator cuff strain and glenohumeral kinematics was evaluated during active abduction.Twelve fresh-frozen cadaver shoulders with intact rotator cuff were used in this study. 50% and 100% wide (full-thickness) crescent-shaped (n = 6) and reverse L-shaped tears (n = 6) were created in the supraspinatus tendon and strain and kinematics were measured during active humeral elevation until 30°.Both tear shapes and sizes led to an increase in internal rotation, supraspinatus loading force and superior translation of the humerus. For the "100% wide" tear size, an anterior translation was observed in the "crescent-shaped" group, while in the "reverse L-shaped" group this translation occurred mainly in the posterior direction. Strain was higher in the infraspinatus during the first 25° of abduction in comparison with the supraspinatus tendon in both tear shape groups. An analysis of the anterior and posterior tear borders showed a higher strain concentration on the same side of the tear in the "50%" and "100% wide crescent-shaped" group.The influence of different tear shapes was evident in the translation in the anterior-posterior direction as both led to an oppositely directed translation of the humeral head. The strain analysis showed a stress-shielding effect of the infraspinatus at the beginning of the abduction. Therefore, special attention must be paid to correctly identify the tear extension and adequately reconstruct the rotator cuff footprint. Moreover, the constant location of the maximum strain in the "crescent-shaped tear" group may lead to an earlier progression in contrast to the "reverse L-shaped tear" group.

Published

2023

9. Clinical Acuity in the Emergency Department and Injury Severity Determine Hospital Admission of Older Patients with Low Energy Falls: Outcomes from a Prospective Feasibility Study

Author

Valentin Clemens, Maximilian M. Saller, Rupert Meller, Carl Neuerburg, Christian Kammerlander, Wolfgang Boecker, Matthias Klein, and Vera Pedersen

Subjects

older adult, low energy fall, hospital admission, tablet-based assessment, clinical frailty scale, emergency severity index, Charlson comorbidity index, injury severity, General Medicine

Abstract

Background: Low energy falls (LEF) in older adults constitute a relevant cause for emergency department (ED) visits, hospital admission and in-hospital mortality. Patient-reported outcome measures containing information about patients’ medical, mental and social health problems might support disposition and therapy decisions. We investigated the value of a tablet-based (self-)assessment in predicting hospital admission and in-hospital mortality. Methods: Patients 65 years or older, consecutively presenting with LEF to our level I trauma center ED (from November 2020 to March 2021), were eligible for inclusion in this prospective observational study. The primary endpoint was hospital admission; secondary endpoints were in-hospital mortality and the use of the tablet for self-reported assessment. Multivariate logistic regression models were calculated to measure the association between clinical findings and endpoints. Results: Of 618 eligible patients, 201 patients were included. The median age was 82 years (62.7% women). The hospital admission rate was 45.3% (110/201), with an in-hospital mortality rate of 3.6% (4/110). Polypharmacy (odds ratio (OR): 8.48; 95% confidence interval (95%CI) 1.21–59.37, p = 0.03), lower emergency severity index (ESI) scores (OR: 0.33; 95%CI 0.17–0.64, p = 0.001) and increasing injury severity score (ISS) (OR: 1.54; 95%CI 1.32–1.79, p < 0.001) were associated with hospital admission. The Charlson comorbidity index (CCI) was significantly associated with in-hospital mortality (OR: 2.60; 95%CI: 1.17–5.81, p = 0.03). Increasing age (OR: 0.94; 95%CI: 0.89–0.99, p = 0.03) and frailty (OR: 0.71; 95%CI: 0.51–0.99, p = 0.04) were associated with the incapability of tablet use. Conclusions: The severity of fall-related injuries and the clinical acuity are easily accessible, relevant predictors for hospital admission. Tablet-based (self-)assessment may be feasible and acceptable during ED visits and might help facilitate comprehensive geriatric assessments during ED stay.

Published

2023

10. Systematic review of molecular pathways in burn wound healing

Author

Annika S. Walter, Elias Volkmer, Gerd Gauglitz, Wolfgang Böcker, and Maximilian M. Saller

Subjects

Emergency Medicine, Surgery, General Medicine, Critical Care and Intensive Care Medicine

Published

2023

11. Patients With Dupuytren Disease Use Excessive Grip Force When Lifting and Holding Small Objects, Independent of the Degree of Contracture

Author

Elisabeth M. Haas-Lützenberger, Katharina Pippich, Kathrin Allgöwer, Joachim Hermsdörfer, Riccardo Giunta, Maximilian M. Saller, and Elias Volkmer

Subjects

Rehabilitation, Physical Therapy, Sports Therapy and Rehabilitation

Published

2023

12. Hypoxic pre-conditioned adipose-derived stem/progenitor cells embedded in fibrin conduits promote peripheral nerve regeneration in a sciatic nerve graft model

Author

Julius M Mayer, Christian Krug, Maximilian M Saller, Annette Feuchtinger, Riccardo E Giunta, Elias Volkmer, and Thomas Holzbach

Subjects

adipose-derived progenitor cells, adipose-derived multipotent stem/progenitor cell, autologous nerve graft, fibrin conduit, hypoxia, hypoxic pre-conditioning, nerve defect, nerve tissue engineering, peripheral nerve regeneration, regenerative medicine, Neurology. Diseases of the nervous system, RC346-429

Abstract

Recent results emphasize the supportive effects of adipose-derived multipotent stem/progenitor cells (ADSPCs) in peripheral nerve recovery. Cultivation under hypoxia is considered to enhance the release of the regenerative potential of ADSPCs. This study aimed to examine whether peripheral nerve regeneration in a rat model of autologous sciatic nerve graft benefits from an additional custom-made fibrin conduit seeded with hypoxic pre-conditioned (2% oxygen for 72 hours) autologous ADSPCs (n = 9). This treatment mode was compared with three others: fibrin conduit seeded with ADSPCs cultivated under normoxic conditions (n = 9); non-cell-carrying conduit (n = 9); and nerve autograft only (n = 9). A 16-week follow-up included functional testing (sciatic functional index and static sciatic index) as well as postmortem muscle mass analyses and morphometric nerve evaluations (histology, g-ratio, axon density, and diameter). At 8 weeks, the hypoxic pre-conditioned group achieved significantly higher sciatic functional index/static sciatic index scores than the other three groups, indicating faster functional regeneration. Furthermore, histologic evaluation showed significantly increased axon outgrowth/branching, axon density, remyelination, and a reduced relative connective tissue area. Hypoxic pre-conditioned ADSPCs seeded in fibrin conduits are a promising adjunct to current nerve autografts. Further studies are needed to understand the underlying cellular mechanism and to investigate a potential application in clinical practice.

Published

2023

13. Validation of a novel animal model for sciatic nerve repair with an adipose-derived stem cell loaded fibrin conduit

Author

Maximilian M Saller, Rosa-Eva Huettl, Julius M Mayer, Annette Feuchtinger, Christian Krug, Thomas Holzbach, and Elias Volkmer

Subjects

critical-size nerve defect, fibrin conduit, autologous nerve transplant, peripheral nerve regeneration, adipose-derived stem/progenitor cells, sciatic function index, sciatic nerve, re-innervation, axon guidance, peripheral circuitry, Neurology. Diseases of the nervous system, RC346-429

Abstract

Despite the regenerative capabilities of peripheral nerves, severe injuries or neuronal trauma of critical size impose immense hurdles for proper restoration of neuro-muscular circuitry. Autologous nerve grafts improve re-establishment of connectivity, but also comprise substantial donor site morbidity. We developed a rat model which allows the testing of different cell applications, i.e., mesenchymal stem cells, to improve nerve regeneration in vivo. To mimic inaccurate alignment of autologous nerve grafts with the injured nerve, a 20 mm portion of the sciatic nerve was excised, and sutured back in place in reversed direction. To validate the feasibility of our novel model, a fibrin gel conduit containing autologous undifferentiated adipose-derived stem cells was applied around the coaptation sites and compared to autologous nerve grafts. After evaluating sciatic nerve function for 16 weeks postoperatively, animals were sacrificed, and gastrocnemius muscle weight was determined along with morphological parameters (g-ratio, axon density & diameter) of regenerating axons. Interestingly, the addition of undifferentiated adipose-derived stem cells resulted in a significantly improved re-myelination, axon ingrowth and functional outcome, when compared to animals without a cell seeded conduit. The presented model thus displays several intriguing features: it imitates a certain mismatch in size, distribution and orientation of axons within the nerve coaptation site. The fibrin conduit itself allows for an easy application of cells and, as a true critical-size defect model, any observed improvement relates directly to the performed intervention. Since fibrin and adipose-derived stem cells have been approved for human applications, the technique can theoretically be performed on humans. Thus, we suggest that the model is a powerful tool to investigate cell mediated assistance of peripheral nerve regeneration.

Published

2018

14. Micro-Structural and Biomechanical Evaluation of Bioresorbable and Conventional Bone Cements for Augmentation of the Proximal Femoral Nail.

Author

Linhart C, Kistler M, Saller M, Greiner A, Lampert C, Kassube M, Becker CA, Böcker W, and Ehrnthaller C

Abstract

Osteoporotic proximal femur fractures are on the rise due to demographic change. The most dominant surgical treatment option for per/subtrochanteric fractures is cephalomedullary nailing. As it has been shown to increase primary stability, cement augmentation has become increasingly popular in the treatment of osteoporotic per/subtrochanteric femur fractures. The ultimate goal is to achieve stable osteosynthesis, allowing for rapid full weight-bearing to reduce possible postoperative complications. In recent years, bioresorbable bone cements have been developed and are now mainly used to fill bone voids. The aim of this study was to evaluate the biomechanical stability as well as the micro-structural behaviour of bioresorbable bone cements compared to conventional polymethylmethacrylate (PMMA)-cements in a subtrochanteric femur fracture model. Biomechanical as well as micro-computed tomography morphology analysis revealed no significant differences in both bone cements, as they showed equal mechanical stability and tight interdigitation into the spongious bone of the femoral head. Given the positive risk/benefit ratio for bioresorbable bone cements, their utilisation should be evaluated in future clinical studies, making them a promising alternative to PMMA-bone cements.

Published

2023

15. A Review of Biomechanical and Physiological Effects of Using Poles in Sports.

Author

Saller M, Nagengast N, Frisch M, and Fuss FK

Abstract

The use of poles in sports, to support propulsion, is an integral and inherent component of some sports disciplines such as skiing (cross-country and roller), Nordic walking, and trail running. The aim of this review is to summarize the current state-of-the-art of literature on multiple influencing factors of poles in terms of biomechanical and physiological effects. We evaluated publications in the subfields of biomechanics, physiology, coordination, and pole properties. Plantar pressure and ground reaction forces decreased with the use of poles in all included studies. The upper body and trunk muscles were more active. The lower body muscles were either less active or no different from walking without poles. The use of poles led to a higher oxygen consumption (VO2) without increasing the level of perceived exertion (RPE). Furthermore, the heart rate (HR) tended to be higher. Longer poles reduced the VO2 and provided a longer thrust phase and greater propulsive impulse. The mass of the poles showed no major influence on VO2, RPE, or HR. Solely the activity of the biceps brachii increased with the pole mass.

Published

2023

16. Emerging opportunities and future directions: general discussion.

Author

Althorpe SC, Barford W, Blumberger J, Bungey C, Burghardt I, Datta A, Ghosh S, Giannini S, Grünbaum T, Habershon S, Hammes-Schiffer S, Hay S, Iyengar S, Jones G, Kelly A, Komarova K, Lawrence J, Litman Y, Mannouch J, Manolopoulos D, Martens C, Maurer RJ, Melander M, Rossi M, Sakaushi K, Saller M, Schile A, Sturniolo S, Trenins G, and Worth G

Published

2019

17. Overcoming hypoxia in 3D culture systems for tissue engineering of bone in vitro using an automated, oxygen-triggered feedback loop.

Author

Volkmer E, Otto S, Polzer H, Saller M, Trappendreher D, Zagar D, Hamisch S, Ziegler G, Wilhelmi A, Mutschler W, and Schieker M

Subjects

3T3 Cells, Animals, Bioreactors, Cell Culture Techniques, Hydrogen-Ion Concentration, Mice, Tissue Scaffolds, Automation, Bone and Bones cytology, Cell Hypoxia, Oxygen metabolism, Tissue Engineering

Abstract

Tissue engineering is an attractive approach to heal bony defects. However, three-dimensional cell-scaffold constructs display uneven oxygen supply resulting in inhomogeneous tissue quality. We assessed different strategies to improve oxygen supply in vitro. Scaffolds with differing inner surface were seeded with preosteoblastic cells and cultivated either statically or in perfusion bioreactors. Oxygen concentration and pH were measured in the center of the scaffolds. An inductive feedback mechanism was build to increase bioreactor pump speed according to the oxygen concentrations measured within the scaffolds. While pH remained stable, oxygen concentration decreased significantly under static conditions within the cell-seeded scaffolds. Reducing the scaffolds' inner surface as well as increasing perfusion speeds in bioreactors resulted in improved oxygen supply. We conclude that improving oxygen supply to three dimensional culture systems for bone tissue engineering is feasible in an automated manner. Culture conditions have to be adapted to each cell-scaffold system individually.

Published

2012