Thursday, 18th of April 2024, 20:00
RONEXPRIM, together with the external partner, Malvern Panalytical, have the pleasure to invite you to participate at the webinar:
Understanding and controlling stability of LNPs using DLS and NTA
Lipid Nanoparticles (LNPs) as delivery vectors hold immense promise for nucleic acid-based gene therapy, oncology, and vaccine development. Platform technologies that characterize critical quality attributes (CQAs) of LNPs will help realize that promise.
This webinar highlights the need to understand and control the stability of LNPs from formulation development to manufacturing. We will discuss two light scattering techniques, Dynamic Light Scattering (DLS) and Nanoparticle Tracking Analysis (NTA), and how they are used to measure LNP physicochemical properties, including particle size, particle size distribution, and particle concentration.
This webinar highlights the need to understand and control the stability of LNPs from formulation development to manufacturing. We will discuss two light scattering techniques, Dynamic Light Scattering (DLS) and Nanoparticle Tracking Analysis (NTA), and how they are used to measure LNP physicochemical properties, including particle size, particle size distribution, and particle concentration.
We will also discuss how these physicochemical properties relate to LNP CQAs.
Speakers:
Who should attend?
• Any scientist involved in the development of LNP-based therapeutics, including LNP formulation scientists, LNP analytical
development scientists, and LNP discovery scientists
• Drug discovery scientists with an interest in drug design, medicinal chemistry and cancer biology
What you will learn?
• We will discuss two light scattering techniques, Dynamic Light Scattering (DLS) and Nanoparticle Tracking Analysis (NTA),
and how they are used to measure LNP physicochemical properties, including particle size, particle size distribution, and
particle concentration
• We will also discuss how these physiochemical properties relate to LNP CQAs
and how they are used to measure LNP physicochemical properties, including particle size, particle size distribution, and
particle concentration
• We will also discuss how these physiochemical properties relate to LNP CQAs