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Containment of BiohazardsLaboratory InfectionCost ControlAir MovementsLaboratoriesQuarantineLegg-Calve-Perthes DiseaseDisease OutbreaksSingle-Payer SystemPatient IsolatorsSmallpoxMedical WasteVentilationHazardous SubstancesDracunculus NematodeBioterrorismAerosolsEnvironment, ControlledMicrobiologyInsurance, HospitalizationDracunculiasisGenetic EngineeringPatient IsolationInfection ControlAir MicrobiologyPlant InfertilityCommunicable Disease ControlAnimals, LaboratoryMedical Laboratory SciencePoliomyelitisSecurity Measures

Biosafety evaluation of the DNA extraction protocol for Mycobacterium tuberculosis complex species, as implemented at the Instituto Nacional de Salud, Colombia. (57/121)

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Biosafety level 2 model of pneumonic plague and protection studies with F1 and Psa. (58/121)

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Structure of the recombinant alphavirus Western equine encephalitis virus revealed by cryoelectron microscopy. (59/121)

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Biological safety cabinetry. (60/121)

The biological safety cabinet is the one piece of laboratory and pharmacy equipment that provides protection for personnel, the product, and the environment. Through the history of laboratory-acquired infections from the earliest published case to the emergence of hepatitis B and AIDS, the need for health care worker protection is described. A brief description with design, construction, function, and production capabilities is provided for class I and class III safety cabinets. The development of the high-efficiency particulate air filter provided the impetus for clean room technology, from which evolved the class II laminar flow biological safety cabinet. The clean room concept was advanced when the horizontal airflow clean bench was manufactured; it became popular in pharmacies for preparing intravenous solutions because the product was protected. However, as with infectious microorganisms and laboratory workers, individual sensitization to antibiotics and the advent of hazardous antineoplastic agents changed the thinking of pharmacists and nurses, and they began to use the class II safety cabinet to prevent adverse personnel reactions to the drugs. How the class II safety cabinet became the mainstay in laboratories and pharmacies is described, and insight is provided into the formulation of National Sanitation Foundation standard number 49 and its revisions. The working operations of a class II cabinet are described, as are the variations of the four types with regard to design, function, air velocity profiles, and the use of toxins. The main certification procedures are explained, with examples of improper or incorrect certifications. The required levels of containment for microorganisms are given. Instructions for decontaminating the class II biological safety cabinet of infectious agents are provided; unfortunately, there is no method for decontaminating the cabinet of antineoplastic agents.  (+info)

Containment of bioaerosol infection risk by the Xpert MTB/RIF assay and its applicability to point-of-care settings. (61/121)

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Biosafety and biosecurity as essential pillars of international health security and cross-cutting elements of biological nonproliferation. (62/121)

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Development and application of a tool to assess laboratory hygiene in contained-use facilities. (63/121)

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Evaluating biological containment strategies for pollen-mediated gene flow. (64/121)

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