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- Klinik und Poliklinik für Unfall-, Hand-, Plastische und Wiederherstellungschirurgie (Chirurgische Klinik II) (7) (remove)
Purpose. Copal\(^®\) spacem is a new PMMA bone cement for fabricating spacers. This study compares elution of gentamicin, elution of vancomycin, and compressive strength of Copal\(^®\) spacem and of Palacos\(^®\) R+G at different vancomycin loadings in the powder of the cements. We hypothesized that antibiotic elution of Copal\(^®\) spacem is superior at comparable compressive strength. Methods. Compression test specimens were fabricated using Copal\(^®\) spacem manually loaded with 0.5 g gentamicin and additionally 2 g, 4 g, and 6 g of vancomycin per 40 g of cement powder (COP specimens) and using 0.5 g gentamicin premixed Palacos\(^®\) R+G manually loaded with 2 g, 4 g, and 6 g of vancomycin per 40 g of cement powder (PAL specimens). These specimens were used for determination of gentamicin and vancomycin elution (in fetal calf serum, at 22°C) and for determination of compressive strength both prior and following the elution tests. Results. Cumulative gentamicin concentrations (p < 0.005) and gentamicin concentration after 28 days (p ≤ 0.043) were significantly lower for COP specimens compared to PAL specimens. Cumulative vancomycin concentrations were significantly higher (p ≤ 0.043) for COP specimens after the second day. Vancomycin concentrations after 28 days were not significantly higher for the Copal specimens loaded with 2 g and 4 g of vancomycin. Compressive strength was not significantly different between COP specimens and PAL specimens before elution tests. Compressive strength after the elution tests was significantly lower (p = 0.005) for COP specimens loaded with 2 g of vancomycin. Conclusion. We could not demonstrate consistent superior antibiotic elution from Copal\(^®\) spacem compared to Palacos\(^®\) R+G for fabricating gentamicin and vancomycin loaded spacers. The results do not favor Copal\(^®\) spacem over Palacos\(^®\) R+G for the use as a gentamicin and vancomycin biantibiotic-loaded spacer.
Intra- and interobserver reliability of glenoid fracture classifications by Ideberg, Euler and AO
(2018)
Background:
Representing 3%-5% of shoulder girdle injuries scapula fractures are rare. Furthermore, approximately 1% of scapula fractures are intraarticularfractures of the glenoid fossa. Because of uncertain fracture morphology and limited experience, the treatment of glenoid fossa fractures is difficult. The glenoid fracture classification by Ideberg (1984) and Euler (1996) is still commonly used in literature. In 2013 a new glenoid fracture classification was introduced by the AO. The purpose of this study was to examine the new AO classification in clinical practice in comparison with the classifications by Ideberg and Euler.
Methods:
In total CT images of 84 patients with glenoid fossa fractures from 2005 to 2018 were included. Parasagittal, paracoronary and axial reconstructions were examined according to the classifications of Ideberg, Euler and the AO by 3 investigators (orthopedic surgeon, radiologist, student of medicine) at three individual time settings. Inter- and intraobserver reliability of the three classification systems were ascertained by computing Inter- and Intraclass (ICCs) correlation coefficients using Spearman's rank correlation coefficient, 95%-confidence intervals as well as F-tests for correlation coefficients.
Results:
Inter- and intraobserver reliability for the AO classification showed a perspicuous coherence (R = 0.74 and R = 0.79). Low to moderate intraobserver reliability for Ideberg (R = 0.46) and Euler classification (R = 0.41) was found. Furthermore, data show a low Interobserver reliability for both Ideberg and Euler classification (R < 0.2). Both the Inter- and Intraclass reliability using AO is significantly higher than those using Ideberg and Euler (p < 0.05). Using the new AO classification, it was possible to find a proper class for every glenoid fossa fracture. On average, according to Euler classification 10 of 84 fractures were not classifiable whereas to Ideberg classification 21 of 84 fractures were not classifiable.
Conclusion:
The new AO classification system introduced 2013 facilitates reliable grading of glenoid fossa fractures with high inter- and intraobserver reliability in 84 patients using CT images. It should possibly be applied in order to enable a valid, reliable and consistent academic description of glenoid fossa fractures. The established classifications by Euler and Ideberg are not capable of providing a similar reliability.
Background:
Reverse oblique distal radio-ulnar joint (DRUJ) configuration is assumed to show inferior postoperative results in ulnar-shortening osteotomy due to osteoarthritis, as the joint force pressure in the DRUJ may be increased. An evaluation and comparison of the postoperative functional results with regard to clinical and radiographic signs of arthritis among different DRUJ configurations was carried out retrospectively.
Methods:
Sixty-two patients after ulnar shortening osteotomy were included. The minimum follow-up was 5 years. Preoperative x-rays were assessed for the DRUJ configuration according to the Tolat classification, whereas postoperative radiographs were evaluated with regard to signs of osteoarthritis using the Kallgren-Lawrence-Score. Functional results were evaluated using the disabilities of the arm, shoulder and hand (DASH) and Mayo Wrist Score and measuring range of motion and grip strength.
Results:
Significantly better functional results were found in patients with parallel configuration of the DRUJ (Tolat type 1 configuration) with regard to DASH score, grip strength, and supination compared with nonparallel configurations. In the Tolat type 1, configurated DRUJ mean DASH score was 9 compared with 18 in the Tolat type 2 and 3 groups. Apart from supination, no differences were observed in range of motion among groups.
Conclusion:
Although long-term postoperative range of motion failed to display statistically significant differences between DRUJ configurations except for supination, better results regarding grip strength and DASH scores were seen in a parallel-aligned DRUJ configuration. Although onset of osteoarthritis does not seem to become apparent within the observation period, nonparallel aligned configuration predisposes to inferior results.
Background:
Vascular damage in polytrauma patients is associated with high mortality and morbidity. Therefore, specific clinical implications of vascular damage with fractures in major trauma patients are reassessed.
Methods:
This comprehensive nine-year retrospective single center cohort study analyzed demography, laboratory, treatment and outcome data from 3689 patients, 64 patients with fracture-associated vascular injuries were identified and were compared to a control group.
Results:
Vascular damage occurred in 7% of patients with upper and lower limb and pelvic fractures admitted to the trauma room. Overall survival was 80% in pelvic fracture and 97% in extremity fracture patients and comparable to non-vascular trauma patients. Additional arterial damage required substantial fluid administration and was visible as significantly anemia and disturbed coagulation tests upon admission. Open procedures were done in over 80% of peripheral extremity vascular damage. Endovascular procedures were predominant (87%) in pelvic injury.
Conclusion:
Vascular damage is associated with high mortality rates especially in combination with pelvic fractures. Initial anemia, disturbed coagulation tests and the need for extensive pre-clinical fluid substitution were observed in the cohort with vascular damage. Therefore, fast diagnosis and early interventional and surgical procedures are necessary to optimize patient-specific outcome.
Background:
The amount of fatty degeneration (FD) has major impact on the clinical result and cuff integrity after rotator cuff repair. A quantitative analysis with magnet resonance imaging (MRI) spectroscopy was employed to analyze possible correlation of FD with tendon retraction, tendon thickness and patients’ characteristics in full thickness supraspinatus tears.
Methods:
Forty-two patients with full-thickness supraspinatus tears underwent shoulder MRI including an experimental spectroscopic sequence allowing quantification of the fat fraction in the supraspinatus muscle belly. The amount of fatty degeneration was correlated with tendon retraction, tendon thickness, patients’ age, gender, smoker status, symptom duration and body mass index (BMI). Patients were divided in to three groups of retraction (A) 0-10 mm (n=), (B) 11-20 mm (n=) and (C) < 21 mm (n=) and the means of FD for each group were calculated.
Results:
Tendon retraction (R = 0.6) and symptom duration (R = 0.6) correlated positively, whereas tendon thickness correlated negatively (R = − 0.6) with the amount of FD. The fat fraction increased significantly with tendon retraction: Group (A) showed a mean fat mount of 3.7% (±4%), group (B) of 16.7% (±8.2%) and group (C) of 37.5% (±19%). BMI, age and smoker-status only showed weak to moderate correlation with the amount of FD in this cohort.
Conclusion:
MRI spectroscopy revealed significantly higher amount of fat with increasing grade of retraction, symptom duration and decreased tendon thickness. Thus, these parameters may indirectly be associated with the severity of tendon disease.
Background:
Minimally invasive pedicle screw fixation has less approach-related morbidity than open screw placement and is allegedly less traumatizing on paravertebral muscles, as there is no requirement to mobilize and retract the adjacent muscle portion. The approach-related long-term effects to the morphology of the paravertebral muscles are unknown. The purpose of this study was to compare the long-term amount of fatty degeneration of the multifidus muscle in patients treated with a classical open or a minimally invasive approach.
Methods:
Fourteen Patients meeting inclusion criteria were selected. In all patients a singular fracture of the thoracolumbar spine with a two-level posterior instrumentation was treated, either using an open approach or a minimally invasive approach. All patients underwent quantitative MRI spectroscopy for quantification of the fatty degeneration in the multifidus muscle as a long-term proof for muscle loss after minimum 4-year follow-up. Clinical outcome was assessed using Oswestry Low Back Pain Disability Questionnaire, SF-36 and VA-scale for pain.
Results:
The minimally invasive approach group failed to show less muscle degeneration in comparison to the open group. Total amount of fatty degeneration was 14.22% in the MIS group and 12.60% in the open group (p = 0.64). In accordance to MRI quantitative results there was no difference in the clinical outcome after a mean follow up of 5.9 years (±1.8).
Conclusion:
As short-term advantages of minimal invasive screw placement have been widely demonstrated, no advantage of the MIS, displaying a significant difference in the amount of fatty degeneration and resulting in a better clinical outcome could be found. Besides the well-known short-term advantage of minimally invasive pedicle screw placement, a long-term advantage, such as less muscle degeneration and thus superior clinical results, compared to the open approach could not be shown.
Improved treatment options for the degenerative joint disease osteoarthritis (OA) are of major interest, since OA is one of the main sources of disability, pain, and socioeconomic burden worldwide [202]. According to epidemiological data, already 27 million people suffer from OA in the US [23]. Moreover, the WHO expects OA to be the fourth most common cause of disability in 2020 [203], illustrating the need for effective and long-lasting therapy options of severe cartilage defects. Despite numerous clinically available products for the treatment of cartilage defects [62], the development of more cartilage-specific materials is still at the beginning.
Hyaluronic acid (HA) is a major component of the cartilaginous extracellular matrix (ECM) and inherently creates a cell-friendly niche by providing cell attachment and migration sites. Furthermore, it is known that the functional groups of HA are well suited for chemical modification. These characteristics render HA an attractive material for hydrogel-based tissue engineering approaches. Poly(glycidol) (PG) as chemical crosslinker basically features similar chemical characteristics as the widely used poly(ethylene glycol) (PEG), but provides additional side groups at each repeating unit that can be further chemically functionalized. With the introduction of PG as multifunctional crosslinker for HA gels, a higher cross-linking density and, accordingly, a greater potential for biomimetic functionalization may be achieved. However, despite the mentioned potential benefits, PG has not been used for cartilage regeneration approaches so far.
The initial aim of the study was to set up and optimize a HA-based hydrogel for the chondrogenic differentiation of mesenchymal stromal cells (MSCs), using different amounts and variations of cross-linkers. Therefore, the hydrogel composition was optimized by the utilization of different PEG diacrylate (PEGDA) concentrations to cross-link thiol-modified HA (Glycosil, HA-SH) via Michael addition. We aimed to generate volumestable scaffolds that simultaneously enable a maximum of ECM deposition. Histological and biochemical analysis showed 0.4% PEGDA as the most suitable concentration for these requirements (Section 5.1.2).
In order to evaluate the impact of a differently designed cross-linker on MSC chondrogenesis, HA-SH was cross-linked with PEGTA (0.6%) and compared to PEGDA (0.4%) in a next step. Following this, acrylated PG (PG-Acr) as multifunctional cross-linker alternative to acrylated PEG was evaluated. It provides around five times more functional groups when utilized in PG-Acr (0.6%) HA-SH hydrogels compared to PEGTA (0.6%) HA-SH hydrogels, thus enabling higher degrees of biomimetic functionalization. Determination of cartilage-specific ECM components showed no substantial differences between both cross-linkers while the deposition of cartilaginous matrix appeared more homogeneous in HA-SH PG-Acr gels. Taken together, we were able to successfully increase the possibilities for biomimetic functionalization in the developed HA-SH hydrogel system by the introduction of PG-Acr as cross-linker without negatively affecting MSC chondrogenesis (Section 5.1.3).
The next part of this thesis focused extensively on the biomimetic functionalization of PG-Acr (0.6%) cross-linked HA-SH hydrogels. Here, either biomimetic peptides or a chondrogenic growth factor were covalently bound into the hydrogels.
Interestingly, the incorporation of a N-cadherin mimetic (HAV), a collagen type II binding (KLER), or a cell adhesion-mediating peptide (RGD) yielded no improvement of MSC chondrogenesis. For instance, the covalent binding of 2.5mM HAV changed morphology of cell nuclei and reduced GAG production while the incorporation of 1.0mM RGD impaired collagen production. These findings may be attributed to the already supportive conditions of the employed HA-based hydrogels for chondrogenic differentiation. Most of the previous studies reporting positive peptide effects on chondrogenesis have been carried out in less supportive PEG hydrogels or in significantly stiffer MeHA-based hydrogels [99, 101, 160]. Thus, the incorporation of peptides may be more important under unfavorable conditions while inert gel systems may be useful for studying single peptide effects (Section 5.2.1).
The chondrogenic factor transforming growth factor beta 1 (TGF-b1) served as an example for growth factor binding to PG-Acr. The utilization of covalently bound TGF-b1 may thereby help overcome the need for repeated administration of TGF-b1 in in vivo applications, which may be an advantage for potential clinical application. Thus, the effect of covalently incorporated TGF-b1 was compared to the effect of the same amount of TGF-b1 without covalent binding (100nM TGF-b1) on MSC chondrogenesis. It was successfully demonstrated that covalent incorporation of TGF-b1 had a significant positive effect in a dose-dependent manner. Chondrogenesis of MSCs in hydrogels with covalently bound TGF-b1 showed enhanced levels of chondrogenesis compared to hydrogels into which TGF-b1 was merely mixed, as shown by stronger staining for GAGs, total collagen, aggrecan and collagen type II. Biochemical evaluation of GAG and collagen amounts, as well as Western blot analysis confirmed the histological results. Furthermore, the positive effect of covalently bound TGF-b1 was shown by increased expression of chondrogenic marker genes COL2A1, ACAN and SOX9. In summary, covalent growth factor incorporation utilizing PG-Acr as cross-linker demonstrated significant positive effects on chondrogenic differentiation of MSCs (Section 5.2.2).
In general, PG-Acr cross-linked HA hydrogels generated by Michael addition represent a versatile hydrogel platform due to their high degree of acrylate functionality. These hydrogels may further offer the opportunity to combine several biological modifications, such as the incorporation of biomimetic peptides together with growth factors, within one cell carrier.
A proof-of-principle experiment demonstrated the suitability of pure PG gels for studying single peptide effects. Here, the hydrogels were generated by the utilization of thiol-ene-click reaction. In this setting, without the supportive background of hyaluronic acid, MSCs showed enhanced chondrogenic differentiation in response to the incorporation of 1.0mM HAV. This was demonstrated by staining for GAGs, the cartilage-specific ECM molecules aggrecan and type II collagen, and by increased GAG and total collagen amounts shown by biochemical analysis. Thus, pure PG gels exhibit the potential to study the effects and interplay of peptides and growth factors in a highly modifiable, bioinert hydrogel environment.
The last section of the thesis was carried out as part of the EU project HydroZONES that aims to develop and generate zonal constructs. The importance of zonal organization has attracted increased attention in the last years [127, 128], however, it is still underrepresented in tissue engineering approaches so far. Thus, the feasibility of zonal distribution of cells in a scaffold combining two differently composed hydrogels was investigated. A HA-SH(FMZ) containing bottom layer was generated and a pure PG top layer was subsequently cast on top of it, utilizing both times thiol-ene-click reaction. Indeed, stable, hierarchical constructs were generated that allowed encapsulated MSCs to differentiate chondrogenically in both zones as shown by staining for GAGs and collagen type II, and by quantification of GAG amount. Thus, the feasibility of differently composed zonal hydrogels utilizing PG as a main component was successfully demonstrated (Section 5.4).
With the first-time utilization and evaluation of PG-Acr as versatile multifunctional cross-linker for the preparation of Michael addition-generated HA-SH hydrogels in the context of cartilage tissue engineering, a highly modifiable HA-based hydrogel system was introduced. It may be used in future studies as an easily applicable and versatile toolbox for the generation of biomimetically functionalized hydrogels for cell-based cartilage regeneration. The introduction of reinforcement structures to enhance mechanical resistance may thereby further increase the potential of this system for clinical applications.
Additionally, it was also demonstrated that thiol-ene clickable hydrogels can be used for the generation of cell-laden, pure PG gels or for the generation of more complex, coherent zonal constructs. Furthermore, thiol-ene clickable PG hydrogels have already been further modified and successfully been used in 3D bioprinting experiments [204]. 3D bioprinting, as part of the evolving biofabrication field [205], offers the possibilities to generate complex and hierarchical structures, and to exactly position defined layers, yet at the same time alters the requirements for the utilized hydrogels [159, 206–209]. Since a robust chondrogenesis of MSCs was demonstrated in the thiol-ene clickable hydrogel systems, they may serve as a basis for the development of hydrogels as so called bioinks which may be utilized in more sophisticated biofabrication processes.