Singular secular Kuznets-like period realized amid industrial transformation in US FDA medical devices: a perspective on growth from 1976 to 2020.

INTRODUCTION: Since inception, the United States (US) Food and Drug Administration (FDA) has kept a robust record of regulated medical devices (MDs). Based on these data, can we gain insight into the innovation dynamics of the industry, including the potential for industrial transformation?. AREAS COVERED: Using premarket notifications (PMNs) and approvals (PMAs) data, it is shown that from 1976 to 2020 the total composite (PMN+PMA) metric follows a single secular period: 20.5 years (applications - peak-to-peak: 1992-2012; trough: 2002) and 26.5 years (registrations - peak-to-peak: 1992-2019; trough: 2003), with a peak-to-trough relative percentage difference of 24% and 28%, respectively. Importantly, PMNs and PMAs independently present as an inverse structure. EXPERT OPINION: The evidence suggests that MD innovation is driven by a singular secular Kuznets-like cyclic phenomenon (independent of economic crises) derived from a fundamental shift from simple (PMNs) to complex (PMAs) MDs. Portentously, while the COVID-19 crisis may not affect the overriding dynamic, the anticipated yet significant (~25%) MD innovation drop may be potentially attenuated with attentive measures by MD stakeholders. Limitations of this approach and further thoughts complete this perspective.

Analysis of the renewed European Medical Device Regulations in the frame of the non - EU regulatory landscape during the COVID facilitated change.

The term "Medical devices" includes technology-based devices or articles, both basic and complex. Due to these types of variations, a strict, robust, transparent, and sustainable regulatory framework is required. In recent clinical practice, incidents including the breast implant and the hip replacement crisis have made it necessary to improve the regulatory and compliance approaches for the industry to ensure the manufacturing and distribution of safe and innovative MDs within the EU. In response to this, the EU revised the laws governing medical devices and in vitro diagnostics to align with the developments of the sector, address critical safety issues and support innovation. The new regulation (EU) 2017/745 on Medical Devices (MDR) is now applicable from May 26 2021 and the In Vitro Diagnostic Medical Devices Regulation (EU) 2017/746 will take effect from May 2022.In this review, we aim to provide an update on the new Medical Device Regulations in the context of the current medical needs of the world, and also to give a glimpse at the non-EU regulatory landscape. Finally, we take a look at the closed-system transfer devices (CSTD) and COVID facilitated changes promoting demand for continuous improvement and trends in the pharmaceutical and medical industry related areas.

[POCT-management during the first wave of Covid-19 in France. Results of a national survey leaded by the SFBC-POCT Working Group]. / Gestion de la biologie délocalisée lors de la première vague de Covid-19 en France. Résultats de l'enquête nationale menée par le groupe de travail des EBMD de la SFBC.

During the first wave of Covid-19 in France, in spring 2020, healthcare institution's laboratory had to adapt itself quickly to the growing demand for emergency biology, in particular by reorganizing their POCT analyzers: redeployment of analyzers and/or new installations. In order to analyze this management, a subgroup of 15 hospital biologists from the SFBC Working Group "Biochemical markers of Covid-19" sent, in fall 2020, an on-line survey to French hospital laboratories using POCT. Answers analysis (n = 86) shows a territorial disparity related to the severity of the first wave: increased activity essentially in red zones, management of unexpected situations, training of additional nursing staff for 40 % of the laboratories... The survey also showed simplification of aspects related to accreditation those periods of health crisis. An additional survey, carried out in the spring of 2021, showed good overall satisfaction of the healthcare services (n = 139) concerning the services provided by biology in the POCT sector. Because of their great adaptation capacity, the laboratories and their POCT-teams have played a key role in the management of the first wave of Covid-19 in France. However, the success of these organizations requires an essential collaboration between laboratories and healthcare services. The results of this survey are fundamental in the context of the prolongation of the pandemia throughout the world with a POCT sector appearing to be growing.

Rapid determination of infectious SARS-CoV-2 in PCR-positive samples by SDS-PMA assisted RT-qPCR.

The ongoing COVID-19 pandemic has generated a global health crisis that needs well management of not only patients but also environments to reduce SARS-CoV-2 transmission. The gold standard RT-qPCR method is sensitive and rapid to detect SARS-CoV-2 nucleic acid, but does not answer if PCR-positive samples contain infectious virions. To circumvent this problem, we report an SDS-propidium monoazide (PMA) assisted RT-qPCR method that enables rapid discrimination of live and dead SARS-CoV-2 within 3 h. PMA, a photo-reactive dye, can react with viral RNA released or inside inactivated SARS-CoV-2 virions under assistance of 0.005% SDS, but not viral RNA inside live virions. Formation of PMA-RNA conjugates prevents PCR amplification, leaving only infectious virions to be detected. Under optimum conditions, RT-qPCR detection of heat-inactivated SARS-CoV-2 resulted in larger than 9 Ct value differences between PMA-treated and PMA-free groups, while less than 0.5 Ct differences were observed in the detection of infectious SARS-CoV-2 ranging from 20 to 5148 viral particles. Using a cutoff Ct difference of 8.6, this method could differentiate as low as 8 PFU live viruses in the mixtures of live and heat-inactivated virions. Further experiments showed that this method could successfully monitor the natural inactivation process of SARS-CoV-2 on plastic surfaces during storage with comparable results to the gold standard plaque assay. We believe that the culture-free method established here could be used for rapid and convenient determination of infectious SARS-CoV-2 virions in PCR-positive samples, which will facilitate better control of SARS-CoV-2 transmission.

Capsid integrity quantitative PCR to determine virus infectivity in environmental and food applications - A systematic review.

Capsid integrity quantitative PCR (qPCR), a molecular detection method for infectious viruses combining azo dye pretreatment with qPCR, has been widely used in recent years; however, variations in pretreatment conditions for various virus types can limit the efficacy of specific protocols. By identifying and critically synthesizing forty-one recent peer-reviewed studies employing capsid integrity qPCR for viruses in the last decade (2009-2019) in the fields of food safety and environmental virology, we aimed to establish recommendations for the detection of infectious viruses. Intercalating dyes are effective measures of viability in PCR assays provided the viral capsid is damaged; viruses that have been inactivated by other causes, such as loss of attachment or genomic damage, are less well detected using this approach. Although optimizing specific protocols for each virus is recommended, we identify a framework for general assay conditions. These include concentrations of ethidium monoazide, propidium monoazide or its derivates between 10 and 200 µM; incubation on ice or at room temperature (20 - 25 °C) for 5-120 min; and dye activation using LED or high light (500-800 Watts) exposure for periods ranging from 5 to 20 min. These simple steps can benefit the investigation of infectious virus transmission in routine (water) monitoring settings and during viral outbreaks such as the current COVID-19 pandemic or endemic diseases like dengue fever.