Formation of Protein Nanoparticles in Microdroplet Flow Reactors

Nanoparticles are increasingly being used for biological applications, such as drug delivery and gene transfection. Different biological and bioinspired building blocks have been used for generating such particles, including lipids and synthetic polymers. Proteins are an attractive class of material for such applications due to their excellent biocompatibility, low immunogenicity, and self-assembly characteristics. Stable, controllable, and homogeneous formation of protein nanoparticles, which is key to successfully delivering cargo intracellularly, has been challenging to achieve using conventional methods. In order to address this issue, we employed droplet microfluidics and utilized the characteristic of rapid and continuous mixing within microdroplets in order to produce highly monodisperse protein nanoparticles. We exploit the naturally occurring vortex flows within microdroplets to prevent nanoparticle aggregation following nucleation, resulting in systematic control over the particle size and monodispersity. Through combination of simulation and experiment, we find that the internal vortex velocity within microdroplets determines the uniformity of the protein nanoparticles, and by varying parameters such as protein concentration and flow rates, we are able to finely tune nanoparticle dimensional properties. Finally, we show that our nanoparticles are highly biocompatible with HEK-293 cells, and through confocal microscopy, we determine that the nanoparticles fully enter into the cell with almost all cells containing them. Due to the high throughput of the method of production and the level of control afforded, we believe that the approach described in this study for generating monodisperse protein-based nanoparticles has the potential for intracellular drug delivery or for gene transfection in the future.

[1]  P. Dittrich,et al.  Continuous Electroformation of Gold Nanoparticles in Nanoliter Droplet Reactors , 2022, Angewandte Chemie.

[2]  J. Moffat,et al.  Identifying cell receptors for the nanoparticle protein corona using genome screens , 2022, Nature Chemical Biology.

[3]  B. Marelli,et al.  Microencapsulation of High-Content Actives Using Biodegradable Silk Materials. , 2022, Small.

[4]  F. Ghadessy,et al.  Phase-separating peptides for direct cytosolic delivery and redox-activated release of macromolecular therapeutics , 2022, Nature Chemistry.

[5]  J. Mascola,et al.  Safety and immunogenicity of a ferritin nanoparticle H2 influenza vaccine in healthy adults: a phase 1 trial , 2022, Nature Medicine.

[6]  J. Lahann,et al.  Protein Nanoparticles: Uniting the Power of Proteins with Engineering Design Approaches , 2022, Advanced science.

[7]  S. Linse,et al.  pH-Responsive Capsules with a Fibril Scaffold Shell Assembled from an Amyloidogenic Peptide. , 2021, Small.

[8]  D. Issadore,et al.  Microfluidic formulation of nanoparticles for biomedical applications. , 2021, Biomaterials.

[9]  Z. Toprakcioglu,et al.  Shear-mediated sol-gel transition of regenerated silk allows the formation of Janus-like microgels , 2021, Scientific Reports.

[10]  Y. Perrie,et al.  Silk Nanoparticle Manufacture in Semi-Batch Format. , 2020, ACS biomaterials science & engineering.

[11]  O. Morozova,et al.  Protein nanoparticles: Cellular uptake, intracellular distribution, biodegradation and induction of cytokine gene expression. , 2020, Nanomedicine : nanotechnology, biology, and medicine.

[12]  C. Becker,et al.  Continuous Flow Reactors from Microfluidic Compartmentalization of Enzymes within Inorganic Microparticles , 2020, ACS applied materials & interfaces.

[13]  Z. Toprakcioglu,et al.  A Microfluidic Co‐Flow Route for Human Serum Albumin‐Drug–Nanoparticle Assembly , 2020, Chemistry.

[14]  H. Santos,et al.  Microfluidics: Microfluidics for Production of Particles: Mechanism, Methodology, and Applications (Small 9/2020) , 2020 .

[15]  E. Gazit,et al.  Biocompatible Hybrid Organic/Inorganic Micro-Hydrogels Promote Bacterial Adherence and Eradication in Vitro and in Vivo. , 2020, Nano letters.

[16]  Z. Toprakcioglu,et al.  Attoliter protein nanogels from droplet nanofluidics for intracellular delivery , 2020, Science Advances.

[17]  F. Caruso,et al.  Glycogen as a Building Block for Advanced Biological Materials , 2019, Advanced materials.

[18]  Jun Liu,et al.  Activatable Protein Nanoparticles for Targeted Delivery of Therapeutic Peptides. , 2018, Advanced materials.

[19]  Wen-Di Li,et al.  Top-down fabrication of shape-controlled, monodisperse nanoparticles for biomedical applications. , 2018, Advanced drug delivery reviews.

[20]  Julia V. Waldman,et al.  Multicolored Protein Nanoparticles: Synthesis, Characterization, and Cell Uptake. , 2018, Bioconjugate chemistry.

[21]  Aviad Levin,et al.  Hierarchical Biomolecular Emulsions Using 3-D Microfluidics with Uniform Surface Chemistry. , 2017, Biomacromolecules.

[22]  C. Dobson,et al.  Silk micrococoons for protein stabilisation and molecular encapsulation , 2017, Nature Communications.

[23]  Y. S. Zhang,et al.  Interplay between materials and microfluidics , 2017 .

[24]  David L Kaplan,et al.  In vivo bioresponses to silk proteins. , 2015, Biomaterials.

[25]  Gonçalo J L Bernardes,et al.  Advances in chemical protein modification. , 2015, Chemical reviews.

[26]  Peter Strasser,et al.  Particle size effects in the catalytic electroreduction of CO₂ on Cu nanoparticles. , 2014, Journal of the American Chemical Society.

[27]  Eun Seong Lee,et al.  Doxorubicin-loaded human serum albumin nanoparticles surface-modified with TNF-related apoptosis-inducing ligand and transferrin for targeting multiple tumor types. , 2012, Biomaterials.

[28]  D. Kaplan,et al.  Materials fabrication from Bombyx mori silk fibroin , 2011, Nature Protocols.

[29]  J. Yao,et al.  Size Effects on the Optical Properties of Organic Nanoparticles , 2001 .

[30]  P. Srivastava,et al.  A mechanism for the specific immunogenicity of heat shock protein-chaperoned peptides. , 1995, Science.