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Wachstums- und Sekretionsverhalten humaner fetaler Lungenfibroblasten nach Applikation von Gamma-Strahlung in vitro / Growth and secretion behavior of human fetal lung fibroblasts after application of gamma-radiation in vitroWruck, Robert January 2011 (has links) (PDF)
Der wesentliche Dosis limitierende Faktor einer Strahlentherapie thorakaler Malignome ist die Strahlenempfindlichkeit des Lungenparenchymes, da sich mit einer Häufigkeit von 25-75 % aller Patienten ein Strahlenschaden des Lungengewebes entwickeln kann. Die Inzidenz einer Lungenfibrose nach 6- 12 Monaten liegt bei 15-30%. Die Kombination zytostatischer Medikamente mit ionisierender Strahlung kann die Ansprechraten verbessern, kann andererseits die Inzidenz einer Pneumonitis erhöhen. Die konkreten Mechanismen, die zu einer Pneumonitis und einer strahleninduzierten Fibrose führen, sind bislang noch nicht vollständig bekannt. Es wird vermutet, daß die ortsständigen Zellen der Lunge eine aktivere Rolle in der Pathogenese als bisher angenommen, einnehmen. Tiermodelle der Strahlenschädiung der Lunge zeigten ein sehr frühe Expression von TGF-ß-mRNA and fibronectin-mRNA nach Bestrahlung. TGF-ß und Fibronectin sind in der BALF und Serum von an thorakalen Malignomen erkrankten, strahlentherapeutisch behandelten Patienten erhöht. Neben Makrophagen und Typ II Pneumocyten als zelluläre Quellen der genannten Cytokine, sind Fibroblasten in der Lage beide Agentien in erheblichem Umfang zu synthetisieren. Ziele Um die aktive Rolle von Fibroblasten in der Pathogenese der strahleninduzierten Lungenfibrose in Abwesenheit von Entzündungszellen zu untersuchen, bestrahlten wir Lungenfibroblasten in vitro und beobachteten folgende Parameter. 1. Zellwachstum 2. Synthese von Fibronectin 3. Synthese von Kollagen ( Procollagen-I-Peptid) 4. Synthese von TGF-ß1 Methoden Humane fetale Lungenfibroblasten (MRC-5 ,ICN Biochemicals Eschwege ,Deutschland) wurden in DME Medium kultiviert unter Zugabe von 10% FCS plus L-Glutamine, Penicillin G , Amphotericin B und Gentamycin; Luftfeuchtigkeit 100% , Temperatur 37°, CO2 5%, Medienwechsel erfolgten zweimal wöchentlich und 24 Stunden vor den Messungen. 24h nach der Aussaat der Zellen erfolgte die Strahlenapplikation (CO 60; 4.5, 7.5, 10.5 Gy ). Messungen erfolgten an den Tagen 3,6,9,12,15 nach Bestrahlung. Hierfür wurden folgende Materialien verwandt. Fibronectin (ELISA), Takara TGF beta (ELISA), DPC Biermann Procollagen-I-Peptide (ELISA), Takara LDH ( kinetischer Assay), Sigma Cell counts (Zählkammer) Alle Messungen wurden zweimal unternommen. Ergebnisse: 1. Das Zellwachstum wurde dosisabhängig gehemmt. 2. Beginnend am 3 Tag stieg die Syntheserate des Fibronectin dosisabhängig. 3. Ähnliche Beobachtungen wurde bzgl der Procollagen-I-Peptid Synthese beobachtet. 4. TGF-ß Spiegel fanden sich nach Bestrahlung ab Tag 6 bis zum 4-fachen über dem Ausgangswert erhöht und kehrten ziwschen den Tagen 9 und 15 auf das Ausgangsniveau zurück. 5. Eine Erhöhung des LDH wurde nicht beobachtet. Dies zeigte, dass eine Zytolyse kein wesentlichen Einfluß hatte. Disskusion: Bei Bestrahlung humaner fetaler Lungenfibroblasten wird das Zellwachstum dosisabhängig limitiert. Dies wurde nicht durch einen strahlenbedingt erhöhten Zelltod hervorgerufen , da das bestimmte LDH ( ein Marker der Zytolyse) in den Zellkulturüberständen nicht erhöht war. Wir vermuten, das durch Bestrahlung eine Differenzierung von Progenitor Fibroblasten zu postmitotischen Fibrocyten erfolgte, wie auch bereits von anderen Arbeitsgruppen berichtet. TGF-ß fand sich nach Bestrahlung in den Zellkulturüberständen deutlich erhöht. Es wird angenommen , daß TGF-ß eine Schlüsselrolle in der Pathogenese fibrosierender Erkrankungen der Lunge, der Leber, der Niere spielt und ebenso in die Enstehung der durch ionisierende Bestrahlung hervorgerufene Lungenfibrose eingebunden ist. Unsere Experimente haben gezeigt , daß Fibroblasten in der Lage sind große Mengen TGF-ß and Fibronectin - sogar in Abwesenheit von Entzündungszellen- zu erzeugen und sich vermutlich autokrin stimulieren können. Dieser Mechanismus wird als wichtiger Co-Faktor in der Pathobiologie verschiedener zur Fibrose führender Lungenerkrankungen angenommen. Schlussfolgerung Fibroblasten produzieren erhöhte Mengen TGF-ß und Fibronectin nach Applikation ionisierender Strahlung. Sie könnten in der Pathogenese der Strahlenschädigung der Lunge eine aktivere Rolle spielen als bisher angenommen. / Introduction The major dosis limiting factor of radiation therapy of thoracic malignomas is the lung which may develop radiation injury with a frequency of 25-70% of patients .The incidence of lung fibrosis after 6-12 months ist 15-30 %. Combination of cytostatic drugs with ionizid radiation can improve response rates, but may result in a higher incidence of pneumonitis. The exact mechanisms leading to pneumonitis and radiation induced fibrosis of the lung are yet unknown.The structural cells of the lung are of the lung are probably involved in the pathogenesis in a more active way than thougt until now. Animal models of radiation injury of the lung showed a very early expression of TGF-beta -mRNA and fibronectin-mRNA after irradiation. TGF-ß and Fibronectin were elevated in BALF and in serum. Macrophages and type-II-pneumocytes are thought to be the cellular source, but fibroblasts also are capable to synthesize both agents in large amounts. Aims In order to investigate the active role of fibroblasts in the pathogenesis of radiation fibrosis we irradiated human lung fibroblasts in vitro. We focused on following points: 1. cell growth 2. synthesis of fibronectin 3. synthesis of collagen (procollagen-I-peptid) 4. synthesis of TGF-beta-1 Methods Human fetal lung fibroblasts (MRC-5 ,ICN Biochemicals Eschwege ,Germany) cultured in DME-medium plus 10 % FCS plus L-glutamine, penicillin G, amphotericin B and gentamycine; air humidity 100 %, temp. 37°C, CO2 5%; change of medium twice weekly and 24 hr. before measurements. 24hrs. after seeding, application of ionizing radiation (CO 60; 4.5, 7.5, 10.5 Gy ). Measurements on day 3,6,9,12,15 after irradiation: Fibronectin (ELISA), Takara TGF beta (ELISA), DPC Biermann Procollagen-I-Peptide (ELISA), Takara LDH ( kinetic assay), Sigma Cell counts (counting chamber) All measurements have been done twice. Results 1. cell growth was inhibited in a dose dependent manner. 2. Beginning at day 3 cell related synthesis of fibronectin was increased depending on the dose of irradiation. 3. Similar observations were made in synthesis of procollagen-I-peptide. 4. TGF-beta levels were increased four fold after irradiation beginning on day 6 and returned to basal values between day 9 and 15 (the cells treated with 10.5 Gy were an exception. Here we found a furthermore higher secretion rate ). 5. No elevation of LDH was noticed, showing that cytolysis was not important in these effects. Discussion Irradiation of fetal human lung fibroblasts inihibited cell growth in a dose depend manner. This was not due to cell death initiated by ionizing rays, because LDH ( marker of cytolysis) was not elevated in culture supernatants. We assume that irradiation induces differentiation of progenitor-fibroblasts to promitotic fibrocytes as reported by other groups. TGF-beta was considerably elevated in culture supernatants after irradiation. TGF-beta is assumed to play a key role in fibrosing disease of lung, liver and kidney and may be involved in radiation induced lung fibrosis as well. Our experiments show, that fibroblasts are able to produce high amounts of TGF-beta and fibronectins - even if inflammatory cells are absent- and may stimulate themselves in an autocrine manner.This mechanism is thought to be an important co-factor in the pathobiology of different fibrosing disorders of the lung and may be important in radiation injury of the lung as well. Conclusion Fibroblasts produce increased amounts of TGF-beta and fibronectin after irradiation. They may play a more active role in the pathogenesis of radiation injury than thought up to now.
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Integrin αVβ3-Directed Contraction by Connective Tissue Cells : Role in Control of Interstitial Fluid Pressure and Modulation by Bacterial ProteinsLidén, Åsa January 2006 (has links)
<p>This thesis aimed at studying mechanisms involved in control of tissue fluid homeostasis during inflammation.</p><p>The interstitial fluid pressure (P<sub>IF</sub>) is of importance for control of tissue fluid balance. A lowering of P<sub>IF</sub> <i>in vivo</i> will result in a transport of fluid from the circulation into the tissue, leading to edema. Loose connective tissues that surround blood vessels have an intrinsic ability to take up fluid and swell. The connective tissue cells exert a tension on the fibrous network of the tissues, thereby preventing the tissues from swelling. Under normal homeostasis, the interactions between the cells and the fibrous network are mediated by β1 integrins. Connective tissue cells are in this way actively controlling P<sub>IF</sub>.</p><p>Here we show a previously unrecognized function for the integrin αVβ3, namely in the control of P<sub>IF</sub>. During inflammation the β1 integrin function is disturbed and the connective tissue cells release their tension on the fibrous network resulting in a lowering of P<sub>IF</sub>. Such a lowering can be restored by platelet-derived growth factor (PDGF) -BB. We demonstrated that PDGF-BB restored P<sub>IF</sub> through a mechanism that was dependent on integrin αVβ3. This was shown by the inability of PDGF-BB to restore a lowered P<sub>IF</sub> in the presence of anti-integrin β3 IgG or a peptide inhibitor of integrin αVβ3. PDGF-BB was in addition unable to normalize a lowered P<sub>IF</sub> in β3 null mice. Furthermore, we demonstrated that extracellular proteins from <i>Streptococcus equi</i> modulated αVβ3-mediated collagen gel contraction. Because of the established concordance between collagen gel contraction <i>in vitro</i> and control of P<sub>IF</sub> <i>in vivo</i>, a potential role for these proteins in control of tissue fluid homeostasis during inflammation could be assumed. Sepsis and septic shock are severe, and sometimes lethal, conditions. Knowledge of how bacterial components influence P<sub>IF</sub> and the mechanisms for tissue fluid control during inflammatory reactions is likely to be of clinical importance in treating sepsis and septic shock.</p>
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Integrin αVβ3-Directed Contraction by Connective Tissue Cells : Role in Control of Interstitial Fluid Pressure and Modulation by Bacterial ProteinsLidén, Åsa January 2006 (has links)
This thesis aimed at studying mechanisms involved in control of tissue fluid homeostasis during inflammation. The interstitial fluid pressure (PIF) is of importance for control of tissue fluid balance. A lowering of PIF in vivo will result in a transport of fluid from the circulation into the tissue, leading to edema. Loose connective tissues that surround blood vessels have an intrinsic ability to take up fluid and swell. The connective tissue cells exert a tension on the fibrous network of the tissues, thereby preventing the tissues from swelling. Under normal homeostasis, the interactions between the cells and the fibrous network are mediated by β1 integrins. Connective tissue cells are in this way actively controlling PIF. Here we show a previously unrecognized function for the integrin αVβ3, namely in the control of PIF. During inflammation the β1 integrin function is disturbed and the connective tissue cells release their tension on the fibrous network resulting in a lowering of PIF. Such a lowering can be restored by platelet-derived growth factor (PDGF) -BB. We demonstrated that PDGF-BB restored PIF through a mechanism that was dependent on integrin αVβ3. This was shown by the inability of PDGF-BB to restore a lowered PIF in the presence of anti-integrin β3 IgG or a peptide inhibitor of integrin αVβ3. PDGF-BB was in addition unable to normalize a lowered PIF in β3 null mice. Furthermore, we demonstrated that extracellular proteins from Streptococcus equi modulated αVβ3-mediated collagen gel contraction. Because of the established concordance between collagen gel contraction in vitro and control of PIF in vivo, a potential role for these proteins in control of tissue fluid homeostasis during inflammation could be assumed. Sepsis and septic shock are severe, and sometimes lethal, conditions. Knowledge of how bacterial components influence PIF and the mechanisms for tissue fluid control during inflammatory reactions is likely to be of clinical importance in treating sepsis and septic shock.
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Signal-dependent Translation of the Platelet Transcriptome: The Roles of αIIbβ3 Integrin, Fibrinogen and Fibronectin in Platelet de novo Protein SynthesisAndrews, Marc 21 March 2012 (has links)
Although platelets are anucleate, they do inherit 1500-3000 mRNA transcripts from their megakaryocyte progenitors, in addition to all the machinery essential for protein synthesis; however, there is little understanding why platelets initiate de novo synthesis of these transcripts. Our group demonstrated that fibrinogen (Fg), a ligand of platelet Glycoprotein (GP)IIb-IIIa (αIIbβ3 integrin), is required for platelet P-selectin expression and that engagement of Fg with GPIIb-IIIa is essential for this process. The present study shows that murine platelets incubated with Fg synthesize P-selectin de novo, and this synthesis is blocked by puromycin. A similar effect is also observed when platelets are incubated with fibronectin, another ligand of GPIIb-IIIa. Furthermore, platelets from both ligand- (Fg−/−, von Willebrand factor−/−, apolipoprotein A-IV−/−) and GPIIb-IIIa-deficient mice have altered proteomes. These data suggest an intricate mechanism by which engagement of platelets with their environment triggers signal-dependent translation of the platelet transcriptome, consequently altering the platelet proteome.
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Signal-dependent Translation of the Platelet Transcriptome: The Roles of αIIbβ3 Integrin, Fibrinogen and Fibronectin in Platelet de novo Protein SynthesisAndrews, Marc 21 March 2012 (has links)
Although platelets are anucleate, they do inherit 1500-3000 mRNA transcripts from their megakaryocyte progenitors, in addition to all the machinery essential for protein synthesis; however, there is little understanding why platelets initiate de novo synthesis of these transcripts. Our group demonstrated that fibrinogen (Fg), a ligand of platelet Glycoprotein (GP)IIb-IIIa (αIIbβ3 integrin), is required for platelet P-selectin expression and that engagement of Fg with GPIIb-IIIa is essential for this process. The present study shows that murine platelets incubated with Fg synthesize P-selectin de novo, and this synthesis is blocked by puromycin. A similar effect is also observed when platelets are incubated with fibronectin, another ligand of GPIIb-IIIa. Furthermore, platelets from both ligand- (Fg−/−, von Willebrand factor−/−, apolipoprotein A-IV−/−) and GPIIb-IIIa-deficient mice have altered proteomes. These data suggest an intricate mechanism by which engagement of platelets with their environment triggers signal-dependent translation of the platelet transcriptome, consequently altering the platelet proteome.
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Transcriptional activation induced by snail 1 during epithelial-mesenchymal transitionPorta de la Riva, Montserrat 22 September 2009 (has links)
La transició epiteli-mesènquima (TEM) és un procés en què cèl lules epitelials, immòbils i amb polaritat apico-basal transiten cap un fenotip mesenquimal o fibroblàstic. L'expressió del factor de transcripció snail1 és suficient per induir TEM en cèl lules en cultiu i és necessari per la majoria de les TEM fisiològiques descrites. Snail1 és un membre de la família de proteïnes amb dits de Zinc que reprimeix gens epitelials (com l'E-cadherina) a través de la unió directa a seqüències especifiques dels promotors anomenades caixes E i posterior reclutament de corepressors. La TEM també es caracteritza per l'activació de gens mesenquimals, però el mecanisme pel qual snail1 indueix l'expressió d'aquests és poc conegut. En aquest treball demostrem que snail1 actua a nivell transcripcional per incrementar els nivells dels marcadors mesenquimals FN1 (fibronectina) i LEF1 (de l'anglès, lymphoid enhancer-binding factor 1) a través d'un mecanisme nou per aquesta proteïna de dits de Zn que no requereix ni caixes E ni unió directa a l'ADN. A més a més, mostrem que, per a dur a terme l'activació, snail1 coopera amb dos factors de transcripció ja descrits en relació a la TEM: beta-catenina i NF-kappa-B. Els nostres resultats també proven que l'expressió forçada de la E-cadherina evita aquesta cooperació i conseqüent activació gènica. A banda d'aquest mecanisme, també hem descrit que el factor de transcripció TFCP2c, que no havia estat prèviament relacionat amb TEM, és necessari per l'activació del gen FN1 induïda per snail1. / Epithelial-mesenchymal transition (EMT) is a cellular process by which no motile epithelial, apico-basal-polarized cells transit towards a motile mesenchymal front-backpolarized phenotype. Expression of the transcription factor snail1 is sufficient to induce EMT in cultured cells and it is required for most of the physiological EMTs described. Snail1 is a member of the Zn finger protein family that represses epithelial genes (such as E-cadherin) by directly binding to specific promoter sequences called E-boxes and subsequent recruitment of corepressors. EMT is also accompanied by activation of mesenchymal genes, however, little is known of how snail1 induces their expression.In this work we provide evidence that snail1 acts at the transcriptional level to increase the levels of the mesenchymal FN1 (fibronectin) and LEF1 (lymphoid enhancer-binding factor 1) genes through a novel mechanism for this Zn finger protein that does not require neither E-boxes nor direct binding to DNA. Furthermore, we describe a cooperative action in such mechanism between snail1 and two transcription factors previously related to EMT: beta-catenin and NF-kappaB. Our results also show that restoration of E-cadherin levels prevents such cooperation and subsequent activation. In addition, we also demonstrate that TFCP2c, which had not been previously linked to EMT, is also required for snail1-induced transcriptional activation of the FN1 gene.
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Bacterial Sortase A as a drug targetLarsson, Caroline January 2012 (has links)
Sortase A is a housekeeping enzyme of Gram-positive bacteria that catalyses the anchoring of surface proteins to the bacterial peptidoglycan. The enzyme works to establish an interaction between bacteria and host cells and is essential for pathogenesis. This makes Sortase A a potential suitable target for inhibition, in order to treat bacterial infections. In this degree project Sortase A from Staphylococcus aureus was explored and potential inhibitors were investigated by performing enzyme activity and bacterial binding assays. A robust FRET assay was developed and optimized for a recombinant version of the enzyme and serves as a good starting point for studying inhibition.
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Modulation of pulmonary epithelial to mesenchymal transitions through control of extracellular matrix microenvironmentsBrown, Ashley Carson 07 July 2011 (has links)
Epithelial to mesenchymal transition (EMT), the transdifferentation of an epithelial cell into a mesenchymal fibroblast, is a cellular process necessary for embryonic development and wound healing. However, uncontrolled EMT can result in accumulation of myofibroblasts and excessive deposition of ECM, contributing to the pathological progression of fibrotic diseases such as pulmonary fibrosis. The ability to control EMT is important for development of novel therapeutics for fibrotic pathologies and for designing novel biomaterials for tissue engineering applications seeking to promote EMT for development of complex tissues. EMT is a highly orchestrated process involving the integration of biochemical signals from specific integrin-mediated interactions with extracellular matrix (ECM) proteins and soluble growth factors such as TGFβ. TGFβ, a potent inducer of EMT, is activated via cell contraction-mediated mechanical release of the growth factor from a macromolecular latency complex. Thus TGFβ activity and subsequent EMT may be influenced by the biochemical and biophysical state of the surrounding ECM. Based on these knowns, it was hypothesized that both changes in integrin engagement and increases in substrate rigidity would modulate EMT due to changes in epithelial cell contraction and TGFβ activation. Here we show that integrin-specific interactions with fibronectin (Fn) fragments displaying both the RGD and PHSRN binding sites facilitate cell binding through α5β1 and α3β1 integrins, and lead to maintenance of epithelial phenotype, while Fn fragments displaying only the RGD site facilitate cell binding through αv integrins and lead to EMT. An in depth investigation into α3β1 binding to Fn fragments indicates that binding is dependent on both the presence and orientation of the PHSRN site. Studies investigating the contribution of ECM stiffening on EMT responses show that increasingly rigid Fn substrates are sufficient to induce spontaneous EMT. Analysis of TGFβ-responsive genes implicate TGFβ-expression, activation or signaling as a mechanism for the observed EMT responses. Together these results suggest that the ECM micromechanical environment is a significant contributor to the onset of EMT responses and provide insights into the design of biomaterial-based microenvironments for the control of epithelial cell phenotype.
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Biophysical and Molecular Determinants in Cell Tension-Mediated Fibronectin Unfolding that Drive FibrillogenesisGee, Elaine Pei-San January 2012 (has links)
Assembly of the extracellular matrix (ECM) protein fibronectin (FN) is a mechanical process that involves cell binding to FN through cell surface integrin receptors and application of tensional forces generated in the cell's contractile actin cytoskeleton. Deformation-induced exposure of cryptic sites, defined as buried molecular recognition sites, in FN has been proposed as a mechanism by which cell tension drives FN fibrillogenesis. The primary integrin attachment site on FN is the RGD loop in the 10FNIII domain. In this thesis, I set out to define the molecular biophysical mechanism by which cell tension application at the RGD site promotes unfolding and thereby induces FN-FN self-assembly leading to matrix fibril formation. Chapter 1 of this dissertation provides an overview of the current knowledge behind the biophysical and molecular basis of FN assembly in the ECM and its key role in development and disease. In Chapter 2, steered molecular dynamic simulations show that the 10FNIII domain under force applied through its N-terminus and RGD loop (N-to-RGD) unfolds to a preferred kinetic intermediate with solvent-exposed N-terminal hydrophobic residues in a manner different from past analyses in the literature where force through the N- and C- termini leads to multiple unfolding pathways. Use of single-molecule atomic force spectroscopy in Chapter 3 experimentally reveals that a mechanically stable intermediate of 10FNIII exposed by N-to-RGD pulling shows a length extension that agrees with the predicted kinetic intermediate. Results of biochemical and cellular studies using synthetic peptides with sequences from the 10FNIII intermediate show in Chapter 4 that the twenty-three amino acid sequence that spans the unraveled N-terminus of the predicted intermediate mediates FN multimerization and contains a minimal seven amino acid sequence we call the multimerization motif that is sufficient to induce FN-FN multimer assembly. Finally, Chapter 5 summarizes the new insights supported by this work regarding the role that mechanical forces applied at the cell binding site in 10FNIII plays in the physiological unfolding of FN with respect to FN fibrillogenesis and ECM assembly.
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Biomolecule Functionalization of Diamond Surfaces for Implant Applications - A Theoretical StudyTian, Yuan January 2015 (has links)
Diamond is a promising material with unique chemical properties. In this thesis, nano-scale diamond quantum size effects were investigated using several chemical property indicators. The results show that the chemical properties are strongly dependent on size for film thicknesses smaller than 1 nm (1D), and for nanodiamond particle diameters less than 2 nm (3D). When the sizes exceed these ranges there are no longer any quantum effects. The influence of surface termination coverage on the surface chemical properties has been calculated for the 2×1 reconstructed diamond (100) surface and for the diamond (111) surface. The terminating species included COOH and NH2 groups, which both are beneficial for the immobilization of biomolecules. The results of the calculations show that it is energetically possible to terminate the diamond surfaces up to 100% with NH2, while it is only possible to cover the surfaces up to 50% with COOH species. The reason for the latter result is most probably the larger sterical hindrance amongst the adsorbates. Both types of termination species were shown to influence the diamond surface electronic properties (e.g., HOMO/LUMO levels). In order to extend the diamond utility for biomedical applications, especially implant design, interactions of various growth factors with the diamond surfaces were also simulated. For non-solvent diamond-biomolecule systems, the results show that adhesion affinities are strongly dependent on biomolecule molecular weights. When including a water based solvent in the systems, the results show good physisorption affinities between proteins and diamond. Proteins structures, before and after physisorption, were visualized, and further investigated with respect to electrostatic properties and functional groups. By comparing the biomolecular structural changes during the adhesion processes, it can be concluded that both the general structures, as well as the binding pocket structures, were kept intact after the adhesion to the diamond surfaces (regardless of the adhesion affinities). In addition, the surface electronic potential distributions were maintained, which indicate preserved biomolecule functionalities. / Vascubone
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