Lack of directed V alpha 14-J alpha 281 rearrangements in NK1+ T cells.

NK1.1+ T cells are an unusual subset of TCR alpha beta cells distinguished by their highly restricted V beta repertoire and predominant usage of an invariant V alpha 14-J alpha 281 chain. To assess whether a directed rearrangement mechanism could be responsible for this invariant alpha chain, we have analyzed V alpha 14 rearrangements by polymerase chain reaction and Southern blot in a panel of cloned T-T hybrids derived from thymic NK1.1+ T cells. As expected a high proportion (17/20) of the hybrids had rearranged V alpha 14 to J alpha 281. However, V alpha 14-J alpha 281 rearrangements always occurred on only one chromosome and were accompanied by other V alpha-J alpha rearrangements (not involving V alpha 14) on the homologous chromosome. These data argue that rigorous ligand selection rather than directed rearrangement is responsible for the high frequency of V alpha 14-J alpha 281 rearrangements in NK1.1+ T cells.

The jasmonate pathway.

Plants are faced with many of the same problems as animals-a need for regulation of metabolic processes and reproduction and for defense against enemies. Jasmonates in plants serve key roles in gene and metabolic regulation, defense, responses to trauma, reproduction, and possibly communication. Some remarkable features of plant responses, such as production of repellent volatiles as a defense against herbivorous insects, or the massive transcriptional reprogramming that occurs in response to wounding, are under the control of the jasmonate pathway. Details of the jasmonate signaling pathway are currently at the center of active research that is generating exciting results. The Jasmonate Biochemical Pathway at the STKE Connections Maps is designed to present and keep pace with these developments.

Behaviour evaluation for risk-taking adolescents (BERTA): an easy to use and assess instrument to detect adolescent risky behaviours in a clinical setting.

To create an instrument to be used in an outpatient clinic to detect adolescents prone to risk-taking behaviours. Based on previous research, five identified variables (relationship with parents and teachers, liking going to school, average grades, and level of religiosity) were used to create a screening tool to detect at least one of ten risky behaviours (tobacco, alcohol, cannabis and other illegal drugs use; sexual intercourse and sexual risky behaviour; driving while intoxicated, riding with an intoxicated driver, not always using a seat belt, and not always using a helmet). The instrument was tested using the Barcelona Adolescent Health Survey 1993. A Receiver Operating Characteristics curve was used to find the best cut-off point between high and low risk score. Odds ratios and 95% confidence intervals were calculated to detect at least one risky behaviour and for each individual behaviour. In order to assess its predictive value, the analysis was repeated using the Barcelona Adolescent Health Survey 1999. In both cases, analyses were conducted for the whole sample and for younger and older adolescents. Adolescents with a high-risk score were more likely to take at least one risky behaviour both when the whole sample was analysed and by age groups. With very few exceptions, the Behaviour Evaluation for Risk-Taking Adolescents showed significant odds ratios for each individual variable. CONCLUSION: The Behaviour Evaluation for Risk-Taking Adolescents has shown its potential as an easy to use instrument to screen for risk-taking behaviours. Future research must aim towards assessing this instrument's predictive value in the clinical setting and it's application to other populations.

Nanopartikel am Arbeitsplatz

Nanopartikel sind sehr kleine Partikel, die gezielt so hergestellt sind, dass ihr Durchmesser kleiner als etwa 100 nm ist. Sie werden in der Industrie eingesetzt, weil Materialien mit solch kleinen Dimensionen oft neue Eigenschaften aufweisen, die sie vom Ursprungsmaterial unterscheidet. Das Potenzial für mögliche Gesundheits- und Umwelteffekte von Nanomaterialien wird zurzeit intensiv diskutiert, denn die möglichen Effekte der neuen Eigenschaften auf Umwelt und Gesundheit sind erst unvollständig geklärt. Für die Abklärung der Risiken ist es wichtig, Informationen über die möglichen Expositionen und mögliche Freisetzungen in die Umwelt zu haben. Bisher wurden aber Daten über eingesetzte Stoffmengen und Materialarten selten systematisch erhoben. Wir haben in der Schweiz eine repräsentative Studie durchgeführt, um den Einsatz von Nanopartikeln im gesamten Industriesektor abschätzen zu können. Diese Studie ist unseres Wissens weltweit die erste solche Studie. Sie verwendete die Definition von Nanopartikeln, welche Nanofasern und Agglomerate von Nanopartikeln mit einschließt. Geschätzte 1.300 Arbeiter in 600 Firmen sind direkt an einer Nanopartikelanwendung beteiligt und könnten somit exponiert werden. Dies sind etwa 0,6% der Firmen und etwa 0,08% der Arbeiter des Schweizer Produktionssektors. Um nun zu bestimmen, ob solche Arbeiter mit Nanopartikel in Kontakt kommen oder nicht, stehen verschiedene Messmethoden zur Verfügung. Die aktuelle Technik erlaubt eine quantitative Messung der Anzahl der Partikel in der Luft, deren Masse oder auch Oberfläche. Diese Messgrößen allein geben zwar Hinweise auf die Präsenz von Nanopartikeln, die möglichen Gesundheitseffekte einer Exposition sind aber erst unvollständig abgeklärt und erlauben keine abschließende Risikoanalyse für den Arbeitsplatz. Mehrere Aktionspläne für die Entwicklung eines sicheren und nachhaltigen Umgangs mit Nanomaterialien wurden in den letzten Jahren gestartet (EU, Schweiz). Internationale und nationale Organisationen entwickelten Guidelines und Empfehlungen für industrielle Anwendungen (Internationale Organisation für Normung - ISO, Schweizerische Unfallversicherungsanstalt - SUVA, Bundesanstalt für Arbeitsschutz und Arbeitsmedizin - BAuA, zusammen mit dem Verband der Chemischen Industrie - VCI). Diese generellen Informationen müssen nun in die Industrie transferiert und an die spezifischen Bedürfnisse der betroffenen Unternehmen angepasst werden. Die aufgezeigte, relativ geringe Verbreitung von Nanopartikelanwendungen in der Industrie weist darauf hin, dass heute Schutzmaßnahmen noch proaktiv und kostengünstig entwickelt und eingeführt werden können. Aber sollte die vorhergesagte "Nano-Revolution" wirklich eintreten, ist die Zeit gekommen, jetzt aktiv zu werden. [Autoren]

Nanoparticle usage and protection measures in the manufacturing industry : a representative survey

Addressing the risks of nanoparticles requires knowledge about release into the environment and occupational exposure. However, such information currently is not systematically collected; therefore, this risk assessment lacks quantitative data. The goal was to evaluate the current level of nanoparticle usage in Swiss industry as well as health, safety, and environmental measures, and the number of potentially exposed workers. A representative, stratified mail survey was conducted among 1626 clients of the Swiss National Accident Insurance Fund (SUVA), which insures 80,000 manufacturing firms, representing 84% of all Swiss manufacturing companies (947 companies answered the survey for a 58.3% response rate). The extrapolation to all Swiss manufacturing companies results in 1309 workers (95% confidence interval [CI]: 1073 to 1545) potentially exposed to nanoparticles in 586 companies (95% CI: 145 to 1027). This corresponds to 0.08% of workers (95% CI: 0.06% to 0.09%) and to 0.6% of companies (95% CI: 0.2% to 1.1%). The industrial chemistry sector showed the highest percentage of companies using nanoparticles (21.2%). Other important sectors also reported nanoparticles. Personal protection equipment was the predominant protection strategy. Only a few applied specific environmental protection measures. This is the first nationwide representative study on nanoparticle use in the manufacturing sector. The information gained can be used for quantitative risk assessment. It can also help policymakers design strategies to support companies developing a safer use of nanomaterial. Notingthe current low use of nanoparticles, there is still time to proactively introduce protective methods. If the predicted "nano-revolution" comes true, now is the time to take action. [Supplementary materials are available for this article. Go to the publisher's online edition of Journal of occupational and Environmental Hygiene for the following free supplemental resource: a pdf file containing a detailed description of the approach to statistical analyses, English translation of the questionnaire, additional information for Figure 1, and additional information for the SUVA-code.] [Authors]

Suivi thérapeutique des médicaments (II). La pratique clinique [Therapeutic drug monitoring: clinical practice].

When requesting a blood level measurement in the context of "Therapeutic drug monitoring" (TDM), numerous aspects have to be considered in the pre-analytical and analytical area, as in the integration of associated clinical data. This review presents therapeutic classes for which a clinical benefit of TDM is established or suggested, at least in some settings. For each class of drugs, the main pharmacokinetic, pre-analytical, analytical and clinical aspects are evaluated in the scope of such a monitoring. Each step of the TDM process is important and none should be neglected. Additional clinical trials are however warranted to better establish the exact conditions of use for such a monitoring.

A low number of Swiss companies uses nanoparticles

Nanoparticles <100 nanometres are being introduced into industrial processes, but they are suspected to cause similar negative health effects to ambient particles. Poor knowledge about the scale of introduction has not allowed global risk analysis until now. In 2006 a targeted telephone survey among Swiss companies (1) showed the usage of nanoparticles in a few selected companies but did not provide data to extrapolate to the full Swiss workforce. The purpose of the study presented here was to provide a quantitative estimate of the potential occupational exposure to nanoparticles in Swiss industry. Method: A layered representative questionnaire survey among 1626 Swiss companies of the production sector was conducted in 2007. The survey was a written questionnaire, collecting data about the used nanoparticles, the number of potentially exposed persons in the companies and their protection strategy. Results: The response rate of the study was 58.3%. The number of companies estimated to be using nanoparticles in Switzerland was 586 (95% Confidence Interval 145 to 1027). It is estimated that 1309 workers (95% CI 1073 to 1545) do their job in the same room as a nanoparticle application. Personal protection was shown to be the predominant protection means. Such information is valuable for risk evaluation. The low number of companies dealing with nanoparticles in Switzerland suggests that policy makers as well as health, safety and environmental officers within companies can focus their efforts on a relatively small number of companies or workers. The collected data about types of particles and applications may be used for research on prevention strategies and adapted protection means. However, to reflect the most recent trends, the information presented here has to be continuously updated, and a large-scale inventory of the usage should be considered.