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Minced Cartilage Implantation in Acetabular Cartilage Defects: Case Series with 2-Year Results
(2023)
Objective
The objective was to evaluate clinical outcome and safety of arthroscopic, autologous minced cartilage implantation for acetabular cartilage lesions observed during hip arthroscopy to treat femoroacetabular impingement syndrome (FAIS).
Design
Eleven male patients, average age: 29.4 ± 5.4 years, average body mass index (BMI): 24.2 ± 2.2 kg/m2, scheduled for hip arthroscopy due to FAIS accompanied by an acetabular cartilage lesion were included in the case series. Cartilage tissue was harvested and minced from the loose cartilage flap at the chondrolabral lesion by arthroscopic shaver, augmented with autologous conditioned plasma, implanted into the defect, and fixated by autologous thrombin. Concomitant interventions were performed as indicated. The patients were evaluated preoperatively and at 24-month follow-up, using the International Hip Outcome Tool-12 (iHOT-12) and Visual Analog Scale (VAS) pain score and by magnetic resonance imaging (MRI) using the Magnetic Resonance Observation of Cartilage Repair Tissue (MOCART) grading scale at the 2-year follow-up.
Results
The defect size was on average 3.5 cm2 (1.5-4.5 cm2). From preoperatively to 2 years postoperatively, the iHOT-12 significantly improved from 50.2 ± 18 to 86.5 ± 19 (P < 0.0001), and pain score decreased from 5.6 ± 1.8 to 1.0 ± 1.5 (P < 0.0001) on the Visual Analog Scale pain score. Regarding functional outcome and pain, 10 of the 11 patients and all patients reached the minimal clinically important difference (MCID), respectively. The postoperative average MOCART score was 87.2 (± 9.2). No adverse events or reoperations were observed.
Conclusions
Arthroscopic, autologous minced cartilage implantation for treating full-thickness acetabular cartilage lesions in FAIS shows statistically and clinically significant improvement at short-term follow-up.
In vitro and in vivo analyses of mono- and mixed-species biofilms formed by microbial pathogens
(2022)
Microbial biofilms can be defined as multicellular clusters of microorganisms embedded in a self-produced extracellular matrix (ECM), which is primarily composed of polymeric biomolecules. Biofilms represent one of the most severe burdens in both industry and healthcare worldwide, causing billions of dollars of treatment costs annually because biofilms are inherently difficult to prevent, treat, and eradicate. In health care settings, patients suffering from cystic fibrosis, or patients with medical implants are highly susceptible to biofilm infections. Once a biofilm is formed, it is almost impossible to quantitatively eradicate it by mechanical, enzymatical, chemical, or antimicrobial treatment. Often the only remaining option to fully eradicate the biofilm is removing of the infected implant or body part. The primary reasons for the inherent resistance of biofilms against all forms of antimicrobial treatment are (I) a reduced metabolic activity of biofilm-embedded cells climaxing in the presence of metabolic inactive persister cells, as well as (II) the protective nature of the biofilm matrix acting as a (diffusion) barrier against antimicrobials and the host immune system. Consequently, there is an urgent need to better understand microbial biofilms from a structural and (patho-) physiological point of view in order to be able to develop new treatment strategies.
Therefore, the aims of this study were to investigate fundamental physiological properties of different clinically relevant single and multi-species biofilms, both in vitro and in vivo. Furthermore, the effectiveness of a novel treatment strategy using cold atmospheric pressure plasma was evaluated in vitro to treat biofilms of the pathogenic fungus C. albicans.
In article I, the intracellular and ECM protein inventory of Staphylococcus aureus during in vitro biofilm growth in a flow reactor was analyzed by liquid-chromatography coupled to tandem mass-spectrometry (LC-MS/MS) analysis combined with metabolic footprint analysis. This analysis showed that anaerobiosis within biofilms releases organic acids lowering the ECM pH. This, in turn, leads to protonation of alkaline proteins – mostly ribosomal proteins originating from cell lysis as well as actively secreted virulence factors – resulting in a positive net charge of these proteins. As a consequence, these proteins accumulate within the ECM and form an electrostatic network with negatively charged cell surfaces, eDNA, and metabolites contributing to the overall biofilm stability.
In article II, the in vivo metaproteome of the multi-species biofilm community in cystic fibrosis sputum was investigated. To this end, an innovative protocol was developed allowing the enrichment of microbial cells, the extraction of proteins from a small amount of cystic fibrosis sputum, and subsequent metaproteome analysis. This protocol also allows 16S sequencing, metabolic footprint analysis, and microscopy of the same sample to complement the metaproteome data. Applying this protocol, we were able to significantly enhance microbial protein coverage providing first insights into important physiological pathways during CF lung infection. A key finding was that the arginine deaminase pathway as well as microbial proteases play a so far underappreciated role in CF pathophysiology.
In articles III and IV, a novel treatment strategy for biofilms formed by the important fungal pathogen Candida albicans was evaluated in vitro. Biofilms were treated with two different sources of nonthermal plasma (with the Nonthermal Plasma Jet “kINPen09” as well as with the Microwave-induced plasma torch “MiniMIP”) and the effect on growth, survival, and viability was assessed by counting colony-forming units (CFU), by cell proliferation assays, as well as by live/dead staining combined with fluorescence microscopy, confocal laser scanning microscopy, (CLSM) and atomic force microscopy (AFM). These tests revealed that biofilms were effectively inactivated mostly on the bottom side of biofilms, indicating a great potential of these two plasma sources to fight biofilms.
Application of In Vivo Imaging Techniques and Diagnostic Tools in Oral Drug Delivery Research
(2022)
Drug absorption following oral administration is determined by complex and dynamic interactions between gastrointestinal (GI) physiology, the drug, and its formulation. Since many of these interactions are not fully understood, the COST action on “Understanding Gastrointestinal Absorption-related Processes (UNGAP)” was initiated in 2017, with the aim to improve the current comprehension of intestinal drug absorption and foster future developments in this field. In this regard, in vivo techniques used for the characterization of human GI physiology and the intraluminal behavior of orally administered dosage forms in the GI tract are fundamental to gaining deeper mechanistic understanding of the interplay between human GI physiology and drug product performance. In this review, the potential applications, advantages, and limitations of the most important in vivo techniques relevant to oral biopharmaceutics are presented from the perspectives of different research fields.