Do firms demand temporary workers when they face workload fluctuation? Cross-country firm-level evidence

The growth of temporary employment is one of the most important transformations of labor markets in the past decades. Theoretically, firms' exposure to short-term workload fluctuations is a major determinant of employing temporary workers when employment protection for permanent workers is high. The authors investigate this relationship empirically with establishment-level data in a broad comparative framework. They create two novel data sets by merging 1) data on 18,500 European firms with 2) measures of labor-market institutions for 20 countries. Results show that fluctuations increase the probability of hiring temporary workers by 8 percentage points in countries with strict employment protection laws. No such effect is observed in countries with weaker employment protections. Results are robust to subgroups, subsamples, and alternative estimation strategies

C-Laurdan: Membrane Order Visualization of HEK293t Cells by Confocal Microscopy

Membrane order is a biophysical characteristic dependent on cellular lipid makeup. Cells regulate the membrane structure as it affects membrane-bound protein activity levels and membrane stability. Spatial organization of membrane lipids, such as lipid rafts, is a proposed theory that has been indirectly measured through polarity-sensitive fluorescent dyes. C-Laurdan is one such dye that penetrates plasma and internal membranes. C-Laurdan is excited by a single 405 nm photon and emits in two distinct ranges depending on membrane order. Herein, we present a protocol for staining HEK293t cells with C-Laurdan and acquiring ratiometric images using a revised ImageJ macro and confocal microscopy. An example figure is provided depicting the effects of methyl-β-cyclodextrin, known to remove lipid rafts through cholesterol sequestration, on HEK293t cells. Further image analysis can be performed through region of interest (ROI) selection tools

Analyses and Localization of Serotonin and L-DOPA in Ocular Tissues by Imaging Mass Spectrometry

Imaging mass spectrometry (IMS) allows for visualization of the spatial distribution of proteins, lipids, and other metabolites in a targeted or untargeted approach. The identification of compounds through mass spectrometry combined with the mapping of compound distribution in the sample establishes IMS as a powerful tool for metabolomics. IMS analysis for serotonin will allow researchers to pinpoint areas of deficiencies or accumulations associated with ocular disorders such as serotonin selective reuptake inhibitor optic neuropathy. Furthermore, L-DOPA has shown great promise as a therapeutic approach for disorders such as age-related macular degeneration, and IMS allows for localization, and relative magnitudes, of L-DOPA in the eye. We describe here an end-to-end approach of IMS from sample preparation to data analysis for serotonin and L-DOPA analysis

Analyses and Localization of Phosphatidylcholine and Phosphatidylserine in Murine Ocular Tissue Using Imaging Mass Spectrometry

Imaging mass spectrometry (IMS) allows for spatial visualization of proteins, lipids, and metabolite distributions in a tissue. Identifying these compounds through mass spectrometry, combined with mapping the compound distribution in the sample in a targeted or untargeted approach, renders IMS a powerful tool for lipidomics. IMS analysis for lipid species such as phosphatidylcholine and phosphatidylserine allows researchers to pinpoint areas of lipid deficiencies or accumulations associated with ocular disorders such as age-related macular degeneration and diabetic retinopathy. Here, we describe an end-to-end IMS approach from sample preparation to data analysis for phosphatidylcholine and phosphatidylserine analysis

Isobaric Incorporation of C13-Histidine for the Assessment of Remyelination

Multiple sclerosis is a demyelinating disease of the central nervous system characterized by the loss of the myelin sheath-the nonconductive membrane surrounding neuronal axons. Demyelination interrupts neuronal transmission, which can impair neurological pathways and present a variety of neurological deficits. Prolonged demyelination can damage neuronal axons resulting in irreversible neuronal damage. Efforts have been made to identify agents that can promote remyelination. However, the assessment of remyelination that new therapies promote can be challenging. The method described in this chapter addresses this challenge by using isobaric C13-histidine as a tag for monitoring its incorporation into myelin proteins and thus monitoring the remyelination process

Coastal Ecosystem Investigations with LiDAR (Light Detection and Ranging) and Bottom Reflectance: Lake Superior Reef Threatened by Migrating Tailings

Where light penetration is excellent, the combination of LiDAR (Light Detection And Ranging) and passive bottom reflectance (multispectral, hyperspectral) greatly aids environmental studies. Over a century ago, two stamp mills (Mohawk and Wolverine) released 22.7 million metric tons of copper-rich tailings into Grand Traverse Bay (Lake Superior). The tailings are crushed basalt, with low albedo and spectral signatures different from natural bedrock (Jacobsville Sandstone) and bedrock-derived quartz sands. Multiple Lidar (CHARTS and CZMIL) over-flights between 2008–2016—complemented by ground-truth (Ponar sediment sampling, ROV photography) and passive bottom reflectance studies (3-band NAIP; 13-band Sentinal-2 orbital satellite; 48 and 288-band CASI)—clarified shoreline and underwater details of tailings migrations. Underwater, the tailings are moving onto Buffalo Reef, a major breeding site important for commercial and recreational lake trout and lake whitefish production (32% of the commercial catch in Keweenaw Bay, 22% in southern Lake Superior). If nothing is done, LiDAR-assisted hydrodynamic modeling predicts 60% tailings cover of Buffalo Reef within 10 years. Bottom reflectance studies confirmed stamp sand encroachment into cobble beds in shallow (0-5m) water but had difficulties in deeper waters (>8 m). Two substrate end-members (sand particles) showed extensive mixing but were handled by CASI hyperspectral imaging. Bottom reflectance studies suggested 25-35% tailings cover of Buffalo Reef, comparable to estimates from independent counts of mixed sand particles (ca. 35% cover of Buffalo Reef by >20% stamp sand mixtures)