@article{BassamArtmannHescheleretal.2011,
  author    = {Bassam, Rasha and Artmann, Gerhard and Hescheler, J{\"u}rgen and Graef, T. and Temiz Artmann, Ayseg{\"u}l and Porst, Dariusz and Linder, Peter and Kayser, Peter and Arinkin, Vladimir and Gossmann, Matthias and Digel, Ilya},
  title     = {Alterations in human hemoglobin structure related to red blood cell storage},
  year      = {2011},
  abstract  = {The importance of the availability of stored blood or blood cells, respectively, for urgent transfusion cannot be overestimated. Nowadays, blood storage becomes even more important since blood products are used for epidemiological studies, bio-technical research or banked for transfusion purposes. Thus blood samples must not only be processed, stored, and shipped to preserve their efficacy and safety, but also all parameters of storage must be recorded and reported for Quality Assurance. Therefore, blood banks and clinical research facilities are seeking more accurate, automated means for blood storage and blood processing.},
  subject      = {H{\"a}moglobin},
  language  = {en}
}
@article{UysalCreutzFiratetal.2022,
  author    = {Uysal, Karya and Creutz, Till and Firat, Ipek Seda and Artmann, Gerhard and Teusch, Nicole and Temiz Artmann, Ayseg{\"u}l},
  title     = {Bio-functionalized ultra-thin, large-area and waterproof silicone membranes for biomechanical cellular loading and compliance experiments},
  series = {Polymers},
  volume    = {14},
  journal   = {Polymers},
  number    = {11},
  publisher = {MDPI},
  address   = {Basel},
  issn      = {2073-4360},
  pages     = {2213},
  year      = {2022},
  abstract  = {Biocompatibility, flexibility and durability make polydimethylsiloxane (PDMS) membranes top candidates in biomedical applications. CellDrum technology uses large area, <10 µm thin membranes as mechanical stress sensors of thin cell layers. For this to be successful, the properties (thickness, temperature, dust, wrinkles, etc.) must be precisely controlled. The following parameters of membrane fabrication by means of the Floating-on-Water (FoW) method were investigated: (1) PDMS volume, (2) ambient temperature, (3) membrane deflection and (4) membrane mechanical compliance. Significant differences were found between all PDMS volumes and thicknesses tested (p < 0.01). They also differed from the calculated values. At room temperatures between 22 and 26 °C, significant differences in average thickness values were found, as well as a continuous decrease in thicknesses within a 4 °C temperature elevation. No correlation was found between the membrane thickness groups (between 3-4 µm) in terms of deflection and compliance. We successfully present a fabrication method for thin bio-functionalized membranes in conjunction with a four-step quality management system. The results highlight the importance of tight regulation of production parameters through quality control. The use of membranes described here could also become the basis for material testing on thin, viscous layers such as polymers, dyes and adhesives, which goes far beyond biological applications.},
  language  = {en}
}
@article{MaggakisKelemenBorkKayseretal.2003,
  author    = {Maggakis-Kelemen, C. and Bork, M. and Kayser, Peter and Biselli, Manfred and Artmann, Gerhard},
  title     = {Biological and mechanical quality of red blood cells cultured from human umbilical cord blood stem cells},
  series = {Medical and biological engineering and computing. 41 (2003), H. 3},
  journal   = {Medical and biological engineering and computing. 41 (2003), H. 3},
  isbn      = {0140-0118},
  pages     = {350 -- 356},
  year      = {2003},
  language  = {en}
}
@article{BorkKelemenBisellietal.2000,
  author    = {Bork, M. and Kelemen, C. and Biselli, Manfred and Artmann, Gerhard},
  title     = {Biophysikalische Charakterisierung ex vivo kultivierter menschlicher Erythrozythen},
  series = {Biomedizinische Technik = Biomedical Engineering. 45 (2000), H. s1},
  journal   = {Biomedizinische Technik = Biomedical Engineering. 45 (2000), H. s1},
  isbn      = {1862-278X},
  pages     = {471 -- 472},
  year      = {2000},
  language  = {de}
}
@article{Artmann2000,
  author    = {Artmann, Gerhard},
  title     = {Cellular engineering - a challenge for engineers? / Artmann, G. M.},
  series = {Biomedizinische Technik = Biomedical Engineering. 45 (2000), H. s1},
  journal   = {Biomedizinische Technik = Biomedical Engineering. 45 (2000), H. s1},
  isbn      = {1862-278X},
  pages     = {449},
  year      = {2000},
  language  = {en}
}
@article{ArtmannKelemenPorstetal.1998,
  author    = {Artmann, Gerhard and Kelemen, C. and Porst, Dariusz and B{\"u}ldt, G.},
  title     = {Cellular engineering: Crash tests an menschlichen Erythrozyten geben Aufschluß {\"u}ber versteckte Materialeigenschaften zellul{\"a}rer Proteine / Artmann, G. M. ; Kelemen, Ch. ; Porst, D. ; B{\"u}ldt, G. ; Chien, Shu},
  series = {Biomedizinische Technik / Biomedical Engineering. 43 (1998), H. s1},
  journal   = {Biomedizinische Technik / Biomedical Engineering. 43 (1998), H. s1},
  isbn      = {1862-278},
  pages     = {446 -- 447},
  year      = {1998},
  language  = {en}
}
@article{ArtmannHueckHollwegetal.2000,
  author    = {Artmann, Gerhard and Hueck, I. S. and Hollweg, H. G. and Schmid-Sch{\"o}nbein, G. W.},
  title     = {Chlorpromazine modulates the Morphological Macro- and Microstructure of Endothelial Cells. Hueck, I. S.; Hollweg, H. G.; Schmid-Sch{\"o}nbein, G. W.; Artmann, Gerhard Michael},
  series = {American Journal of Physiology. Cell Physiology. 278 (2000), H. 5},
  journal   = {American Journal of Physiology. Cell Physiology. 278 (2000), H. 5},
  isbn      = {1522-1563},
  pages     = {873 -- 878},
  year      = {2000},
  language  = {en}
}
@article{ArtmannBurnsCanavesetal.2004,
  author    = {Artmann, Gerhard and Burns, Laura and Canaves, Jaume M. and Temiz Artmann, Ayseg{\"u}l},
  title     = {Circular dichroism spectra of human hemoglobin reveal a reversible structural transition at body temperature},
  series = {European Biophysics Journal. 33 (2004), H. 6},
  journal   = {European Biophysics Journal. 33 (2004), H. 6},
  isbn      = {1432-1017},
  pages     = {490 -- 496},
  year      = {2004},
  language  = {en}
}
@article{DigelTemizArtmannNishikawaetal.2004,
  author    = {Digel, Ilya and Temiz Artmann, Ayseg{\"u}l and Nishikawa, K. and Artmann, Gerhard},
  title     = {Cluster air-ion effects on bacteria and moulds},
  series = {Biomedizinische Technik. 49 (2004), H. Erg.-Bd. 2},
  journal   = {Biomedizinische Technik. 49 (2004), H. Erg.-Bd. 2},
  isbn      = {0932-4666},
  pages     = {1040 -- 1041},
  year      = {2004},
  language  = {en}
}
@article{KurzLinderTrzewiketal.2010,
  author    = {Kurz, R. and Linder, Peter and Trzewik, J{\"u}rgen and R{\"u}ffer, M. and Artmann, Gerhard and Digel, Ilya and Rothermel, A. and Robitzki, A. and Temiz Artmann, Ayseg{\"u}l},
  title     = {Contractile tension and beating rates of self-exciting monolayers and 3D-tissue constructs of neonatal rat cardiomyocytes},
  series = {Medical and Biological Engineering and Computing},
  volume    = {48},
  journal   = {Medical and Biological Engineering and Computing},
  number    = {1},
  publisher = {Springer Nature},
  address   = {Cham},
  issn      = {1741-0444},
  doi       = {10.1007/s11517-009-0552-y},
  pages     = {59 -- 65},
  year      = {2010},
  abstract  = {The CellDrum technology (The term 'CellDrum technology' includes a couple of slightly different technological setups for measuring lateral mechanical tension in various types of cell monolayers or 3D-tissue constructs) was designed to quantify the contraction rate and mechanical tension of self-exciting cardiac myocytes. Cells were grown either within flexible, circular collagen gels or as monolayer on top of respective 1-mum thin silicone membranes. Membrane and cells were bulged outwards by air pressure. This biaxial strain distribution is rather similar the beating, blood-filled heart. The setup allowed presetting the mechanical residual stress level externally by adjusting the centre deflection, thus, mimicking hypertension in vitro. Tension was measured as oscillating differential pressure change between chamber and environment. A 0.5-mm thick collagen-cardiac myocyte tissue construct induced after 2 days of culturing (initial cell density 2 x 10(4) cells/ml), a mechanical tension of 1.62 +/- 0.17 microN/mm(2). Mechanical load is an important growth regulator in the developing heart, and the orientation and alignment of cardiomyocytes is stress sensitive. Therefore, it was necessary to develop the CellDrum technology with its biaxial stress-strain distribution and defined mechanical boundary conditions. Cells were exposed to strain in two directions, radially and circumferentially, which is similar to biaxial loading in real heart tissues. Thus, from a biomechanical point of view, the system is preferable to previous setups based on uniaxial stretching.},
  language  = {en}
}