Latest Upcoming Webinars & Online Events

In this webinar, our expert speaker Dr. Ceri Fielding, from the division of infection and immunity at Cardiff University, will discuss the need to understand how viruses interact with NK cells during the development of novel antiviral therapies.

Charge heterogeneity is often a critical quality attribute, which must be monitored throughout the development of a therapeutic protein and during quality control release.

Modern gene editing technologies continue to transform biological research and push the boundaries of what is possible in and out of the lab. This free-to-attend event will provide industry and academic researchers with a platform to discuss some of the most exciting ways gene editing technologies are being deployed to address real-world challenges in areas spanning human health, agriculture, and climate change.

During this webinar, you will discover ways to improve your protein extraction, such as by reducing workflow complexity, improving results from scarce samples, setting up robust assays and working with large sample cohorts.

As a cornerstone of genetic analysis in biological research, quantitative PCR (qPCR) and digital PCR (dPCR) are the most sensitive molecular methods to analyze nucleic acids and play a key role in the development of cell and gene therapies (CGT).

These tools are widely used during CGT development for example in biodistribution, pharmacokinetics and pharmacodynamics of the investigational lead molecule. But many samples, including tissues rich in nucleases, lipids and other inhibiting substances and target molecules that are short or contain modified bases, can be challenging to work with. For these types of samples, assay design using advanced strategies, concentration standards, spike-in controls and validated normalization is key for reliable analyses.

In this webinar, Dr. Kubista will present strategies for implementing reliable qPCR and dPCR analysis in CGT development while highlighting best practices for adhering to MIQE and dMIQE guidelines and the recently released ISO standard, ISO 20395:2019.

Design–build–test–learn (DBTL) cycles are commonly used in biotechnology and in natural product discovery as they provide a systemic and efficient framework for the metabolic engineering of microbes.

A novel platform that automates multiomics analyses of microbes could enable faster and better DBLT cycles for your research. In this webinar, the development and validation of the high-throughput, automated platform using model microbial organisms is described, as well as the recent work in applying the platform to cell factory and natural products engineering.