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2. Using Polycaprolactone Nanofibers for the Proof-of-Concept Construction of the Alveolar-Capillary Interface.

Author

Capandova M, Sedlakova V, Vorac Z, Kotasova H, Dumkova J, Moran L, Jaros J, Antol M, Bohaciakova D, and Hampl A

Subjects
Humans, Basement Membrane, Proof of Concept Study, Polyesters chemistry, Nanofibers chemistry, Pulmonary Alveoli chemistry, Pulmonary Alveoli cytology, Tissue Engineering methods, Tissue Scaffolds
Abstract

The alveolar-capillary interface is the key functional element of gas exchange in the human lung, and disruptions to this interface can lead to significant medical complications. However, it is currently challenging to adequately model this interface in vitro, as it requires not only the co-culture of human alveolar epithelial and endothelial cells but mainly the preparation of a biocompatible scaffold that mimics the basement membrane. This scaffold should support cell seeding from both sides, and maintain optimal cell adhesion, growth, and differentiation conditions. Our study investigates the use of polycaprolactone (PCL) nanofibers as a versatile substrate for such cell cultures, aiming to model the alveolar-capillary interface more accurately. We optimized nanofiber production parameters, utilized polyamide mesh UHELON as a mechanical support for scaffold handling, and created 3D-printed inserts for specialized co-cultures. Our findings confirm that PCL nanofibrous scaffolds are manageable and support the co-culture of diverse cell types, effectively enabling cell attachment, proliferation, and differentiation. Our research establishes a proof-of-concept model for the alveolar-capillary interface, offering significant potential for enhancing cell-based testing and advancing tissue-engineering applications that require specific nanofibrous matrices., (© 2024 The Author(s). Journal of Biomedical Materials Research Part A published by Wiley Periodicals LLC.)

Published
2025
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3. Copper Oxide Nanoparticles Stimulate the Immune Response and Decrease Antioxidant Defense in Mice After Six-Week Inhalation.

Author

Tulinska J, Mikusova ML, Liskova A, Busova M, Masanova V, Uhnakova I, Rollerova E, Alacova R, Krivosikova Z, Wsolova L, Dusinska M, Horvathova M, Szabova M, Lukan N, Stuchlikova M, Kuba D, Vecera Z, Coufalik P, Krumal K, Alexa L, Vrlikova L, Buchtova M, Dumkova J, Piler P, Thon V, and Mikuska P

Subjects
Adaptive Immunity, Animals, Antioxidants, Cytokines, Mice, Oxides, Copper toxicity, Nanoparticles toxicity
Abstract

Copper oxide nanoparticles (CuO NPs) are increasingly used in various industry sectors. Moreover, medical application of CuO NPs as antimicrobials also contributes to human exposure. Their toxicity, including toxicity to the immune system and blood, raises concerns, while information on their immunotoxicity is still very limited. The aim of our work was to evaluate the effects of CuO NPs (number concentration 1.40×10 6 particles/cm 3 , geometric mean diameter 20.4 nm) on immune/inflammatory response and antioxidant defense in mice exposed to 32.5 µg CuO/m 3 continuously for 6 weeks. After six weeks of CuO NP inhalation, the content of copper in lungs and liver was significantly increased, while in kidneys, spleen, brain, and blood it was similar in exposed and control mice. Inhalation of CuO NPs caused a significant increase in proliferative response of T-lymphocytes after mitogenic stimulation and basal proliferative activity of splenocytes. CuO NPs significantly induced the production of IL-12p70, Th1-cytokine IFN-γ and Th2-cytokines IL-4, IL-5. Levels of TNF-α and IL-6 remained unchanged. Immune assays showed significantly suppressed phagocytic activity of granulocytes and slightly decreased respiratory burst. No significant differences in phagocytosis of monocytes were recorded. The percentage of CD3 + , CD3 + CD4 + , CD3 + CD8 + , and CD3 - CD19 + cell subsets in spleen, thymus, and lymph nodes did not differ between exposed and control animals. No changes in hematological parameters were found between the CuO NP exposed and control groups. The overall antioxidant protection status of the organism was expressed by evaluation of GSH and GSSG concentrations in blood samples. The experimental group exposed to CuO NPs showed a significant decrease in GSH concentration in comparison to the control group. In summary, our results indicate that sub-chronic inhalation of CuO NPs can cause undesired modulation of the immune response. Stimulation of adaptive immunity was indicated by activation of proliferation and secretion functions of lymphocytes. CuO NPs elicited pro-activation state of Th1 and Th2 lymphocytes in exposed mice. Innate immunity was affected by impaired phagocytic activity of granulocytes. Reduced glutathione was significantly decreased in mice exposed to CuO NPs., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Tulinska, Mikusova, Liskova, Busova, Masanova, Uhnakova, Rollerova, Alacova, Krivosikova, Wsolova, Dusinska, Horvathova, Szabova, Lukan, Stuchlikova, Kuba, Vecera, Coufalik, Krumal, Alexa, Vrlikova, Buchtova, Dumkova, Piler, Thon and Mikuska.)

Published
2022
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4. Polarized Sonic Hedgehog Protein Localization and a Shift in the Expression of Region-Specific Molecules Is Associated With the Secondary Palate Development in the Veiled Chameleon.

Author

Hampl M, Dumkova J, Kavkova M, Dosedelova H, Bryjova A, Zahradnicek O, Pyszko M, Macholan M, Zikmund T, Kaiser J, and Buchtova M

Abstract

Secondary palate development is characterized by the formation of two palatal shelves on the maxillary prominences, which fuse in the midline in mammalian embryos. However, in reptilian species, such as turtles, crocodilians, and lizards, the palatal shelves of the secondary palate develop to a variable extent and morphology. While in most Squamates, the palate is widely open, crocodilians develop a fully closed secondary palate. Here, we analyzed developmental processes that underlie secondary palate formation in chameleons, where large palatal shelves extend horizontally toward the midline. The growth of the palatal shelves continued during post-hatching stages and closure of the secondary palate can be observed in several adult animals. The massive proliferation of a multilayered oral epithelium and mesenchymal cells in the dorsal part of the palatal shelves underlined the initiation of their horizontal outgrowth, and was decreased later in development. The polarized cellular localization of primary cilia and Sonic hedgehog protein was associated with horizontal growth of the palatal shelves. Moreover, the development of large palatal shelves, supported by the pterygoid and palatine bones, was coupled with the shift in Meox2 , Msx1 , and Pax9 gene expression along the rostro-caudal axis. In conclusion, our results revealed distinctive developmental processes that contribute to the expansion and closure of the secondary palate in chameleons and highlighted divergences in palate formation across amniote species., (Copyright © 2020 Hampl, Dumkova, Kavkova, Dosedelova, Bryjova, Zahradnicek, Pyszko, Macholan, Zikmund, Kaiser and Buchtova.)

Published
2020
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5. Developmental mechanisms driving complex tooth shape in reptiles.

Author

Landova Sulcova M, Zahradnicek O, Dumkova J, Dosedelova H, Krivanek J, Hampl M, Kavkova M, Zikmund T, Gregorovicova M, Sedmera D, Kaiser J, Tucker AS, and Buchtova M

Subjects
Actins metabolism, Animals, Dental Enamel cytology, Dental Enamel metabolism, Dental Enamel ultrastructure, Gene Expression Regulation, Developmental physiology, Lipid Droplets metabolism, Microscopy, Electron, Transmission, Odontogenesis physiology, Tooth, Reptiles anatomy & histology, Reptiles growth & development, Reptiles metabolism
Abstract

Background: In mammals, odontogenesis is regulated by transient signaling centers known as enamel knots (EKs), which drive the dental epithelium shaping. However, the developmental mechanisms contributing to formation of complex tooth shape in reptiles are not fully understood. Here, we aim to elucidate whether signaling organizers similar to EKs appear during reptilian odontogenesis and how enamel ridges are formed., Results: Morphological structures resembling the mammalian EK were found during reptile odontogenesis. Similar to mammalian primary EKs, they exhibit the presence of apoptotic cells and no proliferating cells. Moreover, expression of mammalian EK-specific molecules (SHH, FGF4, and ST14) and GLI2-negative cells were found in reptilian EK-like areas. 3D analysis of the nucleus shape revealed distinct rearrangement of the cells associated with enamel groove formation. This process was associated with ultrastructural changes and lipid droplet accumulation in the cells directly above the forming ridge, accompanied by alteration of membranous molecule expression (Na/K-ATPase) and cytoskeletal rearrangement (F-actin)., Conclusions: The final complex shape of reptilian teeth is orchestrated by a combination of changes in cell signaling, cell shape, and cell rearrangement. All these factors contribute to asymmetry in the inner enamel epithelium development, enamel deposition, ultimately leading to the formation of characteristic enamel ridges., (© 2019 Wiley Periodicals, Inc.)

Published
2020
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6. Inhaled Cadmium Oxide Nanoparticles: Their in Vivo Fate and Effect on Target Organs.

Author

Dumkova J, Vrlikova L, Vecera Z, Putnova B, Docekal B, Mikuska P, Fictum P, Hampl A, and Buchtova M

Subjects
Animals, Cadmium adverse effects, Cadmium blood, Cadmium Compounds blood, Cadmium Compounds chemistry, Cadmium Compounds metabolism, Environmental Exposure, Female, Kidney metabolism, Kidney pathology, Kidney ultrastructure, Liver metabolism, Liver pathology, Liver ultrastructure, Lung metabolism, Lung pathology, Lung ultrastructure, Mice, Nanoparticles chemistry, Oxides blood, Oxides chemistry, Oxides metabolism, Particle Size, Spleen metabolism, Spleen pathology, Spleen ultrastructure, Cadmium Compounds adverse effects, Inhalation, Nanoparticles adverse effects, Oxides adverse effects
Abstract

The increasing amount of heavy metals used in manufacturing equivalently increases hazards of environmental pollution by industrial products such as cadmium oxide (CdO) nanoparticles. Here, we aimed to unravel the CdO nanoparticle destiny upon their entry into lungs by inhalations, with the main focus on the ultrastructural changes that the nanoparticles may cause to tissues of the primary and secondary target organs. We indeed found the CdO nanoparticles to be transported from the lungs into secondary target organs by blood. In lungs, inhaled CdO nanoparticles caused significant alterations in parenchyma tissue including hyperemia, enlarged pulmonary septa, congested capillaries, alveolar emphysema and small areas of atelectasis. Nanoparticles were observed in the cytoplasm of cells lining bronchioles, in the alveolar spaces as well as inside the membranous pneumocytes and in phagosomes of lung macrophages. Nanoparticles even penetrated through the membrane into some organelles including mitochondria and they also accumulated in the cytoplasmic vesicles. In livers, inhalation caused periportal inflammation and local hepatic necrosis. Only minor changes such as diffusely thickened filtration membrane with intramembranous electron dense deposits were observed in kidney. Taken together, inhaled CdO nanoparticles not only accumulated in lungs but they were also transported to other organs causing serious damage at tissue as well as cellular level.

Published
2016
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