Implementing the Lolli-Method and pooled RT-qPCR testing for SARS-CoV-2 surveillance in schools: a pilot project.

PURPOSE: School closures have been used as part of lockdown strategies to contain the spread of SARS-CoV-2, adversely affecting children's health and education. To ensure the accessibility of educational institutions without exposing society to the risk of increased transmissions, it is essential to establish SARS-CoV-2 testing strategies that are child-friendly, scalable and implementable in a daily school routine. Self-sampling using non-invasive saliva swabs combined with pooled RT-qPCR testing (Lolli-Method) has been proven to be a sensitive method for the detection of SARS-CoV-2. METHODS: We conducted a pilot project in Cologne, Germany, designed to determine the feasibility of a large-scale rollout of the Lolli-Method for testing without any additional on-site medical staff in schools. Over a period of three weeks, students from 22 schools were sampled using the Lolli-Method. At the end of the project, teachers were asked to evaluate the overall acceptance of the project. RESULTS: We analyzed a total of 757 pooled RT-qPCRs obtained from 8,287 individual swabs and detected 7 SARS-CoV-2 infected individuals. The Lolli-Method was shown to be a feasible and accepted testing strategy whose application is only slightly disruptive to the daily school routine. CONCLUSION: Our observations suggest that the Lolli-Method in combination with pooled RT-qPCR can be implemented for SARS-CoV-2 surveillance in daily school routine, applicable on a large scale.

Nanomechanics of the Endothelial Glycocalyx: From Structure to Function.

The negatively charged, brush-like glycocalyx covers the surface layer of endothelial cells. This layer of membrane-bound, carbohydrate-rich molecules covers the luminal surface of the endothelium along the entire vascular tree, mostly comprising glycoproteins and proteoglycans. Together with the underlying actin-rich endothelial cortex, 50 to 150 nm beneath the plasma membrane, the endothelial glycocalyx (eGC) is recognized as a vasoprotective nanobarrier and responsive hub. Importantly, both the eGC and cortex are highly dynamic and can adapt their nanomechanical properties (ie, stiffness and height) to changes in the environment. The constant change between a soft and a stiff endothelial surface is imperative for proper functioning of the endothelium. This review defines the nanomechanical properties of the eGC and stresses the underlying mechanisms and factors leading to a disturbed structure-function relationship. Specifically, under inflammatory conditions, the eGC is damaged, resulting in enhanced vascular permeability, tissue edema, augmented leukocyte adhesion, platelet aggregation, and dysregulated vasodilation. An integrated knowledge of the relationship between the nanomechanical properties, structure, and function of the eGC might be key in understanding vascular function and dysfunction. In this context, the clinical aspects for preservation and restoration of proper eGC nanomechanics are discussed, considering the eGC as a potentially promising diagnostic marker and therapeutic target in the near future.