Graeme Clark Collection
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ItemBiocompatibility of Immobilized Aligned Carbon Nanotubes(WILEY-V C H VERLAG GMBH, 2011-04-18)In vivo host responses to an electrode-like array of aligned carbon nanotubes (ACNTs) embedded within a biopolymer sheet are reported. This biocompatibility study assesses the suitability of immobilized carbon nanotubes for bionic devices. Inflammatory responses and foreign-body histiocytic reactions are not substantially elevated when compared to negative controls following 12 weeks implantation. A fibrous capsule isolates the implanted ACNTs from the surrounding muscle tissue. Filamentous nanotube fragments are engulfed by macrophages, and globular debris is incorporated into the fibrous capsule with no further reaction. Scattered leukocytes are observed, adherent to the ACNT surface. These data indicate that there is a minimal local foreign-body response to immobilized ACNTs, that detached fragments are phagocytosed into an inert material, and that ACNTs do not attract high levels of surface fouling. Collectively, these results suggest that immobilized nanotube structures should be considered for further investigation as bionic components.
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ItemConducting polymers, dual neurotrophins and pulsed electrical stimulation - Dramatic effects on neurite outgrowth(ELSEVIER SCIENCE BV, 2010-01-25)In this study the synergistic effect of delivering two neurotrophins simultaneously to encourage neuron survival and neurite elongation was explored. Neurotrophin-3 (NT-3) and brain-derived neurotrophic factor (BDNF) were incorporated into polypyrrole (PPy) during electrosynthesis and the amounts incorporated and released were determined using iodine-125 ((125)I) radio-labelled neurotrophins. Neurite outgrowth from cochlear neural explants grown on the conducting polymer was equivalent to that on tissue culture plastic but significantly improved with the incorporation of NT-3 and BDNF. Neurite outgrowth from explants grown on polymers containing both NT-3 and BDNF showed significant improvement over PPy doped only with NT-3, due to the synergistic effect of both neurotrophins. Neurite outgrowth was significantly improved when the polymer containing both neurotrophins was electrically stimulated. It is envisaged that when applied to the cochlear implant, these conducting and novel polymer films will provide a biocompatible substrate for storage and release of neurotrophins to help protect auditory neurons from degradation after sensorineural hearing loss and encourage neurite outgrowth towards the electrodes.
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ItemCreating conductive structures for cell growth: Growth and alignment of myogenic cell types on polythiophenes(WILEY-BLACKWELL, 2010-10)Conducting polymers provide suitable substrates for the in vitro study of excitable cells, including skeletal muscle cells, due to their inherent conductivity and electroactivity. The thiophene family of conducting polymers offers unique flexibility for tailoring of polymer properties as a result of the ease of functionalization of the parent monomer. This article describes the preparation of films and electrospun fibers from an ester-functionalized organic solvent-soluble polythiophene (poly-octanoic acid 2-thiophen-3-yl-ethyl ester) and details the changes in properties that result from post-polymerization hydrolysis of the ester linkage. The polymer films supported the proliferation and differentiation of both primary and transformed skeletal muscle myoblasts. In addition, aligned electrospun fibers formed from the polymers provided scaffolds for the guided differentiation of linearly aligned primary myotubes, suggesting their suitability as three-dimensional substrates for the in vitro engineering of skeletal muscle tissue.
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ItemPneumococcal meningitis post-cochlear implantation: preventative measures.(Wiley, 2010-11)OBJECTIVE: Both clinical data and laboratory studies demonstrated the risk of pneumococcal meningitis post-cochlear implantation. This review examines strategies to prevent post-implant meningitis. DATA SOURCES: Medline/PubMed database; English articles after 1980. Search terms: cochlear implants, pneumococcus meningitis, streptococcus pneumonia, immunization, prevention. REVIEW METHODS: Narrative review. All articles relating to post-implant meningitis without any restriction in study designs were assessed and information extracted. RESULTS: The presence of inner ear trauma as a result of surgical technique or cochlear implant electrode array design was associated with a higher risk of post-implant meningitis. Laboratory data demonstrated the effectiveness of pneumococcal vaccination in preventing meningitis induced via the hematogenous route of infection. Fibrous sealing around the electrode array at the cochleostomy site, and the use of antibiotic-coated electrode array reduced the risk of meningitis induced via an otogenic route. CONCLUSION: The recent scientific data support the U.S. Food and Drug Administration recommendation of pneumococcal vaccination for the prevention of meningitis in implant recipients. Nontraumatic cochlear implant design, surgical technique, and an adequate fibrous seal around the cochleostomy site further reduce the risk of meningitis.
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ItemPneumococcal meningitis post-cochlear implantation: potential routes of infection and pathophysiology.(Wiley, 2010-11)OBJECTIVE: This review describes the current concept of pneumococcal meningitis in cochlear implant recipients based on recent laboratory studies. It examines possible routes of Streptococcus pneumoniae infection to the meninges in cochlear implant recipients. It also provides insights into fundamental questions concerning the pathophysiology of pneumococcal meningitis in implant recipients. DATA SOURCES: Medline/PubMed database; English articles after 1960. Search terms: cochlear implants, meningitis, pneumococcus, streptococcus pneumonia. REVIEW METHODS: Narrative review. All articles relating to post-implant meningitis without any restriction in study designs were assessed and information extracted. RESULTS: The incidence of pneumococcal meningitis in cochlear implant recipients is greater than that of an age-matched cohort in the general population. Based on the current clinical literature, it is difficult to determine whether cochlear implantation per se increases the risk of meningitis in subjects with no existing risk factors for acquiring the disease. As this question cannot be answered in humans, the study of implant-related infection must involve the use of laboratory animals in order for the research findings to be applicable to a clinical situation. The laboratory research demonstrated the routes of infection and the effects of the cochlear implant in lowering the threshold for pneumococcal meningitis. CONCLUSION: The laboratory data complement the existing clinical data on the risk of pneumococcal meningitis post-cochlear implantation.