| 00:00:00 | Roles of Nanoparticles in Aggregation Pathways, Adverse Immunogenicity and Quality Assessment of Therapeutic Proteins |
| 00:01:32 | NTA history |
| 00:03:19 | NanoSight Technology: How does it work? |
| 00:03:54 | Nanoparticle Tracking Analysis (NTA) – Direct Visualization of Nanoparticles |
| 00:03:54 | Nanoparticle Tracking Analysis (NTA) |
| 00:03:54 | Principle of Measurement |
| 00:04:20 | Sizing: Stokes-Einstein |
| 00:04:20 | Concentration: Particles are Counted by Number |
| 00:04:56 | NTA Detection Limits: Size and Concentration |
| 00:06:02 | NTA Parameters measured – simultaneously, ‘real time’, particle-by-particle...additional benefit |
| 00:07:20 | NanoSight Technology |
| 00:08:09 | Roles of Nanoparticles in Aggregation Pathways, Adverse Immunogenicity and Quality Assessment of Therapeutic Proteins |
| 00:09:57 | Acknowledgments |
| 00:10:15 | Outline |
| 00:10:40 | You never know what you might find until you look, with proper tools |
| 00:11:10 | Causes of Protein Aggregation |
| 00:11:46 | New Insights into Causes of Aggregation from Quantifying Subvisible Particles |
| 00:12:03 | Particle counts (MFI) provide highly sensitive measure of aggregation due to freeze-thawing |
| 00:13:14 | Particles going along for the ride |
| 00:14:02 | Stainless steel nanoparticles shed from filling pump “seed” protein microparticles |
| 00:14:14 | Particle Formation during Vial Filling with an IgG: Early Example |
| 00:14:42 | Positive Displacement Piston Pumps |
| 00:15:07 | Particle-containing Solution from Commercial Vials was Filtered and Repumped |
| 00:15:30 | Particle Shedding during Pumping of Buffer without Protein |
| 00:15:38 | Material Wiped from Piston after 15-ml Pumping Cycle with Buffer |
| 00:15:49 | Nanoparticles Shed from Pump |
| 00:16:04 | Foreign Material in Pumped Buffer Induces |
| 00:16:37 | Freeze-Thawing IVIG with & without Prior Centrifugation: Nanoparticles |
| 00:17:44 | Freeze-Thawing IVIG with and without prior ultracentrifugation: MFI Results |
| 00:18:21 | Role of Nano- and Microparticles on IVIG Particle Formation during Agitation |
| 00:18:38 | Microparticle Concentrations after Initial Agitation and Subsequent Centrifugations |
| 00:18:51 | Nanoparticle Concentrations after Initial Agitation and Subsequent Centrifugation |
| 00:19:06 | Microparticles during agitation |
| 00:19:51 | Nanoparticle Concentrations during Agitation |
| 00:20:31 | Subvisible Particles are Critical Species on the Protein Aggregation Pathway |
| 00:21:08 | Adverse Immunogenicity: When Miracle Drugs Fail |
| 00:22:34 | Immunogenicity: Particles as Adjuvants |
| 00:22:57 | Effects of route of administration on immunogenicity of rmGH |
| 00:23:13 | Particles in rmGH Samples: only nanoparticles in ultracentrifuged sample |
| 00:24:00 | Ultracentrifuged rmGH (week 6): Nanoparticles cause Immunogenicity |
| 00:24:59 | Mishandling of Products by Pharmacies, Clinics and Patients |
| 00:25:36 | Stresses to Protein Therapeutics even during “Proper” Handling for IV Infusion |
| 00:27:18 | Mimicking the infusion setup… |
| 00:27:39 | Saline - particle counts > 1µm |
| 00:28:09 | Saline – total nanoparticle counts |
| 00:28:44 | IVIg in Saline – particle counts > 1µm |
| 00:29:00 | IVIg in Saline – total nanoparticle counts |
| 00:29:37 | IVIg-0.22um- filter FlowCam Images |
| 00:30:10 | Polycarbonate Particles in IV Saline: G3 ID Raman Microspectroscopy |
| 00:31:27 | Current Regulatory Expectations for Analysis of Subvisible Particles |
| 00:33:47 | Conclusions |
| 00:35:04 | 2015 Colorado Protein Stability Conference |
| 00:52:04 | Contact Information |
Recent work by our guest presenter, Dr. John Carpenter (University of Colorado Anschutz Medical Center), discovered that nanoparticles present in solutions of intravenous immunoglobulin (IVIG) serve as precursors for microparticles during pharmaceutically-relevant stresses such as freeze-thawing or agitation. Depletion of nanoparticles (e.g. by ultracentrifugation) prior to stress greatly reduces the rate of microparticle formation. However new nanoparticles can form during the stress.
Also, therapeutic proteins can adsorb to foreign nanoparticles, resulting in particles containing both protein and foreign material. Sources of nanoparticles of foreign materials include filters, filling and transfer pumps, and chromatography columns.
Importantly, nanoparticles of therapeutic proteins (with either protein alone or with foreign materials) can induce adverse immunogenicity. Our recent study of mouse growth hormone in mice documented that samples containing only protein monomers and trace amounts of nanoparticles were highly immunogenic when administered subcutaneously or intravenously.
Taken together, current data show that nanoparticles play important roles in protein aggregation pathways and in adverse immunogenicity. Thus, regulatory agencies are now viewing quantitation and sizing of nanoparticles as important parts of product quality assessment.