Hyaluronic acid (HA) is increasingly used for a number of medical device applications. Since the chemical structure of HA is identical no matter its bacterial or animal origin, it should be the ideal biomaterial. However, short term transient inflammatory reactions are common, while rare long-term adverse events may correlate with subclinical chronic inflammation. Concern has been raised that low molecular weight components or degradation fragments from implanted HA may directly stimulate inflammatory reactions. This study examined a panel of HA molecular weights from the unitary disaccharide up to 1.7 x 10(6) Dalton lengths, in which endotoxin was assayed at a very low level (less than 0.03 EU/mg). The murine cell line RAW 264.7, rat splenocytes, and rat adherent differentiated primary macrophages were assayed for nitric oxide production under a variety of inflammatory conditions plus or minus HA. Under the highest inflammatory states, nitric oxide production was mildly suppressed by HMW-HA while slightly augmented by LMW-HA at mg/mL concentrations. However, at micromolar concentrations fragments below 5000 Daltons, thought to have drug-like qualities, were without effect. These data support the hypothesis that if endotoxin is reduced to an extremely low level, LMW-HA may not directly provoke normal tissue macrophage-mediated inflammatory reactions.
This study examined the effect of hyaluronan (HA) molecular weight on immune response. HA with molecular weights ranging from the unitary disaccharide unit (400 Da) up to 1.7 × 10(6) Da and with very low endotoxin contamination level (less than 0.03 EU/mg) was used. Primary human monocyte/macrophage cultures were assayed for IL-1β production under a variety of inflammatory conditions with or without HA. Under the highest inflammatory states, production of interleukin 1β (IL-1β) was suppressed in the presence of high molecular weight hyaluronan (HMW-HA) and in the presence of low molecular weight hyaluronan (LMW-HA) at mg/mL concentrations. There was variability in the sensitivity of the response to HA fragments with MW below 5000 Da at micromolar concentrations. There was variability in IL-1β cytokine productions from donor to donor in unstimulated human cell cultures. This study supplements our previous published study that investigated the immunogenic effect of HA molecular weights using murine cell line RAW264.6, rat splenocytes, and rat adherent differentiated primary macrophages. These data support the hypothesis that if the amount of endotoxin is reduced to an extremely low level, LMW-HA may not directly provoke normal tissue macrophage-mediated inflammatory reactions.
People can get oral cancers from UV (290-400 nm) exposures. Besides high outdoor UV exposures, high indoor UV exposures to oral tissues can occur when consumers use UV-emitting tanning devices to either tan or whiten their teeth. We compared the carcinogenic risks of skin to oral tissue cells after UVB (290-320 nm) exposures using commercially available 3D-engineered models for human skin (EpiDerm™), gingival (EpiGing™) and oral (EpiOral™) tissues. To compare the relative carcinogenic risks, we investigated the release of cytokines, initial DNA damage in the form of cyclobutane pyrimidine dimers (CPDs), repair of CPDs and apoptotic cell numbers. We measured cytokine release using cytometric beads with flow cytometry and previously developed a fluorescent immunohistochemical assay to quantify simultaneously CPD repair rates and apoptotic cell numbers. We found that interleukin-8 (IL-8) release and the initial CPDs are significantly higher, whereas the CPD repair rates and apoptotic cell numbers are significantly lower for oral compared with skin tissue cells. Thus, the increased release of the inflammatory cytokine IL-8 along with inefficient CPD repair and decreased death rates for oral compared with skin tissue cells suggests that mutations are accumulating in the surviving population of oral cells increasing people's risks for getting oral cancers.
People can expose their oral cavities to UV (290-400 nm) by simply opening their mouths while outdoors. They can also have their oral cavities exposed to UV indoors to different UV-emitting devices used for diagnoses, treatments and procedures like teeth whitening. Because the World Health Organization declared UV radiation as a complete human carcinogen in 2009, we asked if oral tissues are at a similar or higher carcinogenic risk compared to skin tissue. To understand the UVB (290-320 nm)-related carcinogenic risks to these tissues, we measured initial DNA damage in the form of cyclobutane pyrimidine dimers (CPD), the repair rate of CPD (24 h) and the number of apoptotic dead cells over time resulting from increasing doses of erythemally weighted UV radiation. We used commercially available 3D-engineered models of human skin (EpiDerm™), gingival (EpiGingival™) and oral (EpiOral™) tissues and developed an analytical approach for our tri-labeling fluorescent procedure to identify total DNA, CPD and apoptotic cells so we can simultaneously quantify DNA repair rates and dead cells. Both DNA repair and apoptotic cell numbers are significantly lower in oral cells compared with skin cells. The combined results suggest UVB-exposed oral tissues are at a significantly higher carcinogenic risk than skin tissues.
A modified low denaturing temperature PCR (LDT-PCR) method combined with DNA microarray technique is developed in our lab for quick and effective identification of various mutations in an 81 base pair region of Mycobacterium Tuberculosis (MTB) ribosome RNA polymerase subunit B (rpoB) gene associated with rifampin resistance. By incurporation of wild type (wt) allele fragments that had been PCR amplified previously, the target PCR fragments coming from mutant clinical MTB samples were co-denaturized with incorporated wt type allele fragment at 94˚C and then let them randomly form matched structures (homoduplex) and allele mismatch-containing structures (heteroduplex), respectively, when the temperature cooled down to 70˚C. After the temperature was raised to 80˚C, the heteroduplex double stranded fragments were preferentially denatured and resulted in PCR amplification as well as fluorescence incurporation. Since the homoduplex fragments need a higher temperature to be denatured, they were kept in double-stranded status at that temperature and failed to be PCR amplified. By hybridization of LDT-PCR products with the probes spotted on microarray slides, the fluorescent signals representing the presence of gene mutations were detected. We have tested this method on 35 clinical MTB samples and obtained satisfied results.
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