Lipid-Iron Nanoparticle with a Cell Stress Release Mechanism Combined with a Local Alternating Magnetic Field Enables Site-Activated Drug Release

Simple Summary A novel active release system magnetic sphingomyelin-containing liposome encapsulated with indocyanine green, fluorescent marker, or the anticancer drug cisplatin was evaluated. The liposomal sphingomyelin is a target for the sphingomyelinase enzyme, which is released by stressed cells. Thus, sphingomyelin containing liposomes behave as a sensitizer for biological stress situations. In addition, the liposomes were engineered by adding paramagnetic beads to act as a receiver of outside given magnetic energy. The enzymatic activity towards liposomes and destruction caused by the applied magnetic field caused the release of the content from the liposomes. By using these novel liposomes, we could improve the drug release feature of liposomes. The improved targeting and drug-release were shown in vitro and the orthotopic tongue cancer model in mice optical imaging. The increased delivery of cisplatin prolonged the survival of the targeted delivery group versus free cisplatin. Most available cancer chemotherapies are based on systemically administered small organic molecules, and only a tiny fraction of the drug reaches the disease site. The approach causes significant side effects and limits the outcome of the therapy. Targeted drug delivery provides an alternative to improve the situation. However, due to the poor release characteristics of the delivery systems, limitations remain. This report presents a new approach to address the challenges using two fundamentally different mechanisms to trigger the release from the liposomal carrier. We use an endogenous disease marker, an enzyme, combined with an externally applied magnetic field, to open the delivery system at the correct time only in the disease site. This site-activated release system is a novel two-switch nanomachine that can be regulated by a cell stress-induced enzyme at the cellular level and be remotely controlled using an applied magnetic field. We tested the concept using sphingomyelin-containing liposomes encapsulated with indocyanine green, fluorescent marker, or the anticancer drug cisplatin. We engineered the liposomes by adding paramagnetic beads to act as a receiver of outside magnetic energy. The developed multifunctional liposomes were characterized in vitro in leakage studies and cell internalization studies. The release system was further studied in vivo in imaging and therapy trials using a squamous cell carcinoma tumor in the mouse as a disease model. In vitro studies showed an increased release of loaded material when stress-related enzyme and magnetic field was applied to the carrier liposomes. The theranostic liposomes were found in tumors, and the improved therapeutic effect was shown in the survival studies.Peer reviewe

The primordium of a biological joint replacement:Coupling of two stem cell pathways in biphasic ultrarapid compressed gel niches

The impaired temporomandibular joint might be the first to benefit from applied tissue engineering techniques because it is small and tissue growth in larger amounts is challenging. Bone and cartilage require different competing environmental conditions to be cultivated in vitro. But coupling both the osteogenic and cartilaginous pathways of mesenchymal stem cell differentiation in homeostasis will be a key essential to grow osteochondral constructs or even the first biological joint replacement in the future. The aim of this study was to test a single source biomaterial and a single source cell type to engineer a biphasic osteochondral construct in vitro for future in vivo implantation. Ultrarapid tissue engineering techniques were used to create the biphasic matrix and primary human mesenchymal stem cells (MSCs) preconditioned in osteogenic and chondrogenic media were then seeded in opposite portions of the hyper-hydrated collagen gel in order to further substantiate the respective bone-like and cartilage-like layers thus potentially customising the collagen scaffold according to patient needs in regards to future biological joint replacements. After incubation for 7 days to allow cell growth and differentiation, mineralization of the bone-like layer was demonstrated using von Kossa staining and biochemical bone markers. The cartilage-like layer was demonstrated using alcian blue staining and biochemical cartilage markers. Integration of the bone-like and cartilage-like layers to simulate a tidemark layer was achieved through partial setting of the gels. Cell tracking was used to further confirm the establishment of distinct cartilage-like and bone-like areas within the single construct. This is the first report of one homogeneous human MSC population differentiating into dissimilar "bone-like" and "cartilage-like" zones hosted in a biphasic ultrarapid compressed gel phase niche and mimicking a primordial joint-like structure. © 2010 European Association for Cranio-Maxillo-Facial Surgery

Enhancing adhesion and alignment of human gingival fibroblasts on dental implants

Promoting the directional attachment of gingiva to the dental implant leads to the formation of tight connective tissue which acts as a seal against the penetration of oral bacteria. Such a directional growth is mostly governed by the surface texture. Material and methods: In this study, three different methods, mechanical structuring, chemical etching and laser treatment, have been explored for their applicability in promoting cellular attachment and alignment of human primary gingival fibroblasts (HGFIBs). Results: The effectiveness of mechanical structuring was shown as a simple and a cost-effective method to create patterns to align HGIFIBs. Conclusion: Combining mechanical structuring with chemical etching enhanced both cellular attachment and the cellular alignment474661667COORDENAÇÃO DE APERFEIÇOAMENTO DE PESSOAL DE NÍVEL SUPERIOR - CAPES88888.099049/2013-0