Safe use of hazardous chemicals.

This unit provides protocols for some commonly used disposal and decontamination procedures along with analytical techniques that are used to verify that reagents have been decontaminated. Some of the specific reagents covered are diaminobenzidine, ethidium bromide, cyanogen bromide, and chloromethylsilane. With modification, these assays may also be used to determine the concentration of a particular chemical.

Safe use of hazardous chemicals.

This appendix provides protocols for some commonly used disposal and decontamination procedures along with analytical techniques that are used to verify that reagents have been decontaminated. Some of the specific reagents covered are diaminobenzidine, ethidium bromide, cyanogen bromide and chloromethylsilane. With modification, these assays may also be used to determine the concentration of a particular chemical.

Safe use of hazardous chemicals.

This appendix provides protocols for some commonly used disposal and decontamination procedures along with analytical techniques that are used to verify that reagents have been decontaminated. Some of the specific reagents covered are diaminobenzidine, ethidium bromide, cyanogen bromide and chloromethylsilane. With modification, these assays may also be used to determine the concentration of a particular chemical. Precautions are also detailed for routine handling of viable pathogenic microorganisms, as well as all human-derived materials, because they may harbor dangerous pathogens such as human immunodeficiency virus (HIV), hepatitis B virus (HBV), cytomegalovirus (CMV), Epstein-Barr virus (EBV), and a host of bacterial pathogens.

DPI induces mitochondrial superoxide-mediated apoptosis.

The iodonium compounds diphenyleneiodonium (DPI) and diphenyliodonium (IDP) are well-known phagocyte NAD(P)H oxidase inhibitors. However, it has been shown that at high concentrations they can inhibit the mitochondrial respiratory chain as well. Since inhibition of the mitochondrial respiratory chain has been shown to induce superoxide production and apoptosis, we investigated the effect of iodonium compounds on mitochondria-derived superoxide and apoptosis. Mitochondrial superoxide production was measured on both cultured cells and isolated rat-heart submitochondrial particles. Mitochondria function was examined by monitoring mitochondrial membrane potential. Apoptotic pathways were studied by measuring cytochrome c release and caspase 3 activation. Apoptosis was characterized by detecting DNA fragmentation on agarose gel and measuring propidium iodide- (PI-) stained subdiploid cells using flow cytometry. Our results showed that DPI could induce mitochondrial superoxide production. The same concentration of DPI induced apoptosis by decreasing mitochondrial membrane potential and releasing cytochrome c. Addition of antioxidants or overexpression of MnSOD significantly reduced DPI-induced mitochondrial damage, cytochrome c release, caspase activation, and apoptosis. These observations suggest that DPI can induce apoptosis via induction of mitochondrial superoxide. DPI-induced mitochondrial superoxide production may prove to be a useful model to study the signaling pathways of mitochondrial superoxide.

Investigations of phagosomes, mitochondria, and acidic granules in human neutrophils using fluorescent probes.

The oxidative burst is frequently evaluated by the conversion of dihydrorhodamine 123 (DHR) to rhodamine 123 (R123) and hydroethidium (HE) to ethidium with the use of flow cytometry (FCM). Added R123 accumulates in mitochondria, but during phagocytosis R123 originating from DHR has been observed in neutrophil granules. The present study was designed to identify the site of reactive oxygen species (ROS) formation and the intracellular traffic of R123 in neutrophils by using mitochondrial membrane potential probes and the lysosomotropic probe LysoTracker Red, which have not previously been applied to neutrophils. Quiescent and phagocytosing human peripheral blood neutrophils were incubated with DHR, HE, R123, MitoTracker Green (MTG), MitoTracker Red (CMX-Ros), and LysoTracker Red alone and in all combinations of red and green probes, and studied by FCM and confocal laser scanning microscopy (CLSM). Phagosomes were filled with R123 originating from DHR. Phagocytosis also triggered the oxidative burst in oxidative response granules that differed from acidic granules. All the neutrophils stained with mitochondrial and lysosomotropic dyes. Added R123 and MTG selectively accumulated in mitochondria. Added R123, MTG, and DHR increased the fluorescence of CMX-Ros and LysoTracker Red. This is the first FCM and CLSM demonstration of ROS formation in phagosomes. A distinct subpopulation of neutrophil granules, termed oxidative response granules, also was identified. Neutrophil mitochondrial membrane potential may be evaluated by incubating the cells with R123 and MTG, but results with CMX-Ros should be interpreted with caution. HE and DHR seem to measure a common pathway in the oxidative burst. The simultaneous application of several probes for investigations of organelles carries the risk of probe interference.

Mitochondrial complex I inhibitor rotenone induces apoptosis through enhancing mitochondrial reactive oxygen species production.

Inhibition of mitochondrial respiratory chain complex I by rotenone had been found to induce cell death in a variety of cells. However, the mechanism is still elusive. Because reactive oxygen species (ROS) play an important role in apoptosis and inhibition of mitochondrial respiratory chain complex I by rotenone was thought to be able to elevate mitochondrial ROS production, we investigated the relationship between rotenone-induced apoptosis and mitochondrial reactive oxygen species. Rotenone was able to induce mitochondrial complex I substrate-supported mitochondrial ROS production both in isolated mitochondria from HL-60 cells as well as in cultured cells. Rotenone-induced apoptosis was confirmed by DNA fragmentation, cytochrome c release, and caspase 3 activity. A quantitative correlation between rotenone-induced apoptosis and rotenone-induced mitochondrial ROS production was identified. Rotenone-induced apoptosis was inhibited by treatment with antioxidants (glutathione, N-acetylcysteine, and vitamin C). The role of rotenone-induced mitochondrial ROS in apoptosis was also confirmed by the finding that HT1080 cells overexpressing magnesium superoxide dismutase were more resistant to rotenone-induced apoptosis than control cells. These results suggest that rotenone is able to induce apoptosis via enhancing the amount of mitochondrial reactive oxygen species production.

Safe use of hazardous chemicals.

This appendix presents useful basic information, including common abbreviations, useful measurements and data, characteristics of amino acids and nucleic acids, information on radioactivity and the safe use of radioisotopes and other hazardous chemicals, conversions for centrifuges and rotors, characteristics of common detergents, and common conversion factors.

Efficacy of three head-pointing devices for a mouse emulation task.

Today, there are three competing technologies (exemplified by five products) to provide head-pointing mouse emulation. Since the manufacturers of each of these devices claims to provide similar functionality, it can be difficult for the clinician to decide which is the appropriate device for a client. The current study compares the functional performance of the three input technologies using three commercially available devices, the HeadMaster Plus, Tracker 2000, and Tracer. Each device was used to produce a series of drawings of similar complexity until the participants achieved a stable level of performance. The number of trials required to achieve mastery, the speed of drawing at mastery, and the accuracy of drawings was compared for the devices. In addition, the participants were asked about their subjective experience using the devices. Each of the three technologies was fastest for some participants, but the HeadMaster Plus produced the most consistently fast drawing times. Results indicated that although performance of the devices was similar, participant preference was driven by comfort more than by performance. The two fastest devices, the HeadMaster Plus and Tracer, both resulted in complaints regarding comfort, whereas the most comfortable device, the Tracker 2000, was preferred by participants although it was slightly slower in performance.