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256 results on '"Van Lehn, Reid C."'

1. Uncertainty Quantification for Molecular Property Predictions with Graph Neural Architecture Search

Author

Jiang, Shengli, Qin, Shiyi, Van Lehn, Reid C., Balaprakash, Prasanna, and Zavala, Victor M.

Subjects
Computer Science - Machine Learning, Physics - Chemical Physics, Quantitative Biology - Biomolecules
Abstract

Graph Neural Networks (GNNs) have emerged as a prominent class of data-driven methods for molecular property prediction. However, a key limitation of typical GNN models is their inability to quantify uncertainties in the predictions. This capability is crucial for ensuring the trustworthy use and deployment of models in downstream tasks. To that end, we introduce AutoGNNUQ, an automated uncertainty quantification (UQ) approach for molecular property prediction. AutoGNNUQ leverages architecture search to generate an ensemble of high-performing GNNs, enabling the estimation of predictive uncertainties. Our approach employs variance decomposition to separate data (aleatoric) and model (epistemic) uncertainties, providing valuable insights for reducing them. In our computational experiments, we demonstrate that AutoGNNUQ outperforms existing UQ methods in terms of both prediction accuracy and UQ performance on multiple benchmark datasets. Additionally, we utilize t-SNE visualization to explore correlations between molecular features and uncertainty, offering insight for dataset improvement. AutoGNNUQ has broad applicability in domains such as drug discovery and materials science, where accurate uncertainty quantification is crucial for decision-making.

Published
2023
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6. Structure–Property Relationships of Amphiphilic Nanoparticles That Penetrate or Fuse Lipid Membranes

Author

Atukorale, Prabhani U, Guven, Zekiye P, Bekdemir, Ahmet, Carney, Randy P, Van Lehn, Reid C, Yun, Dong Soo, Silva, Paulo H Jacob, Demurtas, Davide, Yang, Yu-Sang, Alexander-Katz, Alfredo, Stellacci, Francesco, and Irvine, Darrell J

Subjects
Nanotechnology, Bioengineering, Boron Compounds, Hydrophobic and Hydrophilic Interactions, Ligands, Lipid Bilayers, Liposomes, Membrane Fusion, Nanoparticles, Particle Size, Permeability, Static Electricity, Structure-Activity Relationship, Medicinal and Biomolecular Chemistry, Organic Chemistry, Biochemistry and Cell Biology
Abstract

The development of synthetic nanomaterials that could embed within, penetrate, or induce fusion between membranes without permanent disruption would have great significance for biomedical applications. Here we describe structure-function relationships of highly water-soluble gold nanoparticles comprised of an ∼1.5-5 nm diameter metal core coated by an amphiphilic organic ligand shell, which exhibit membrane embedding and fusion activity mediated by the surface ligands. Using an environment-sensitive dye anchored within the ligand shell as a sensor of membrane embedding, we demonstrate that particles with core sizes of ∼2-3 nm are capable of embedding within and penetrating fluid bilayers. At the nanoscale, these particles also promote spontaneous fusion of liposomes or spontaneously embed within intact liposomal vesicles. These studies provide nanoparticle design and selection principles that could be used in drug delivery applications, as membrane stains, or for the creation of novel organic/inorganic nanomaterial self-assemblies.

Published
2018

10. Free Energy Analysis of Peptide-Induced Pore Formation in Lipid Membranes by Bridging Atomistic and Coarse-Grained Simulations

Author

Richardson, Joshua D. and Van Lehn, Reid C.

Abstract

Antimicrobial peptides (AMPs) are attractive materials for combating the antimicrobial resistance crisis because they can kill target microbes by directly disrupting cell membranes. Although thousands of AMPs have been discovered, their molecular mechanisms of action are still poorly understood. One broad mechanism for membrane disruption is the formation of membrane-spanning hydrophilic pores which can be stabilized by AMPs. In this study, we use molecular dynamics simulations to investigate the thermodynamics of pore formation in model single-component lipid membranes in the presence of one of three AMPs: aurein 1.2, melittin and magainin 2. To overcome the general challenge of modeling long time scale membrane-related behaviors, including AMP binding, clustering, and pore formation, we develop a generalizable methodology for sampling AMP-induced pore formation. This approach involves the long equilibration of peptides around a pore created with a nucleation collective variable by performing coarse-grained simulations, then backmapping equilibrated AMP-membrane configurations to all-atom resolution. We then perform all-atom simulations to resolve free energy profiles for pore formation while accurately modeling the interplay of lipid–peptide–solvent interactions that dictate pore formation free energies. Using this approach, we quantify free energy barriers for pore formation without direct biases on peptides or whole lipids, allowing us to investigate mechanisms of pore formation for these 3 AMPs that are a consequence of unbiased peptide diffusion and clustering. Further analysis of simulation trajectories then relates variations in pore lining by AMPs, AMP-induced lipid disruptions, and salt bridges between AMPs to the observed pore formation free energies and corresponding mechanisms. This methodology and mechanistic analysis have the potential to generalize beyond the AMPs in this study to improve our understanding of pore formation by AMPs and related antimicrobial materials.

Published
2024
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11. Nanocrystal Assemblies: Current Advances and Open Problems.

Author

Bassani, Carlos L., van Anders, Greg, Banin, Uri, Baranov, Dmitry, Chen, Qian, Dijkstra, Marjolein, Dimitriyev, Michael S., Efrati, Efi, Faraudo, Jordi, Gang, Oleg, Gaston, Nicola, Golestanian, Ramin, Guerrero-Garcia, G. Ivan, Gruenwald, Michael, Haji-Akbari, Amir, Ibáñez, Maria, Karg, Matthias, Kraus, Tobias, Lee, Byeongdu, and Van Lehn, Reid C.

Published
2024
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16. Effect of Particle Diameter and Surface Composition on the Spontaneous Fusion of Monolayer-Protected Gold Nanoparticles with Lipid Bilayers

Author

Van Lehn, Reid C, Atukorale, Prabhani U, Carney, Randy P, Yang, Yu-Sang, Stellacci, Francesco, Irvine, Darrell J, and Alexander-Katz, Alfredo

Subjects
Bioengineering, Nanotechnology, Cell Membrane, Gold, Lipid Bilayers, Metal Nanoparticles, Particle Size, lipid bilayer, gold nanoparticle, surface monolayer, membrane insertion, cell penetration, snorkeling, Nanoscience & Nanotechnology
Abstract

Anionic, monolayer-protected gold nanoparticles (AuNPs) have been shown to nondisruptively penetrate cellular membranes. Here, we show that a critical first step in the penetration process is potentially the fusion of such AuNPs with lipid bilayers. Free energy calculations, experiments on unilamellar and multilamellar vesicles, and cell studies all support this hypothesis. Furthermore, we show that fusion is only favorable for AuNPs with core diameters below a critical size that depends on the monolayer composition.

Published
2013

19. Identifying nonadditive contributions to the hydrophobicity of chemically heterogeneous surfaces via dual-loop active learning.

Author

Kelkar, Atharva S., Dallin, Bradley C., and Van Lehn, Reid C.

Subjects
ACTIVE learning, MOLECULAR dynamics, CONVOLUTIONAL neural networks, HYDROPHOBIC interactions, PROTEIN-protein interactions, MANUFACTURING processes
Abstract

Hydrophobic interactions drive numerous biological and synthetic processes. The materials used in these processes often possess chemically heterogeneous surfaces that are characterized by diverse chemical groups positioned in close proximity at the nanoscale; examples include functionalized nanomaterials and biomolecules, such as proteins and peptides. Nonadditive contributions to the hydrophobicity of such surfaces depend on the chemical identities and spatial patterns of polar and nonpolar groups in ways that remain poorly understood. Here, we develop a dual-loop active learning framework that combines a fast reduced-accuracy method (a convolutional neural network) with a slow higher-accuracy method (molecular dynamics simulations with enhanced sampling) to efficiently predict the hydration free energy, a thermodynamic descriptor of hydrophobicity, for nearly 200 000 chemically heterogeneous self-assembled monolayers (SAMs). Analysis of this dataset reveals that SAMs with distinct polar groups exhibit substantial variations in hydrophobicity as a function of their composition and patterning, but the clustering of nonpolar groups is a common signature of highly hydrophobic patterns. Further molecular dynamics analysis relates such clustering to the perturbation of interfacial water structure. These results provide new insight into the influence of chemical heterogeneity on hydrophobicity via quantitative analysis of a large set of surfaces, enabled by the active learning approach. [ABSTRACT FROM AUTHOR]

Published
2022
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26. Correction: Expanding plastics recycling technologies: chemical aspects, technology status and challenges

Author

Li, Houqian, primary, Aguirre-Villegas, Horacio A., additional, Allen, Robert D., additional, Bai, Xianglan, additional, Benson, Craig H., additional, Beckham, Gregg T., additional, Bradshaw, Sabrina L., additional, Brown, Jessica L., additional, Brown, Robert C., additional, Cecon, Victor S., additional, Curley, Julia B., additional, Curtzwiler, Greg W., additional, Dong, Son, additional, Gaddameedi, Soumika, additional, Estela-García, John E., additional, Hermans, Ive, additional, Kim, Min Soo, additional, Ma, Jiaze, additional, Mark, Lesli O., additional, Mavrikakis, Manos, additional, Olafasakin, Olumide O., additional, Osswald, Tim A., additional, Papanikolaou, Konstantinos G., additional, Radhakrishnan, Harish, additional, Sanchez Castillo, Marco Antonio, additional, Sánchez-Rivera, Kevin L., additional, Tumu, Khairun N., additional, Van Lehn, Reid C., additional, Vorst, Keith L., additional, Wright, Mark M., additional, Wu, Jiayang, additional, Zavala, Victor M., additional, Zhou, Panzheng, additional, and Huber, George W., additional

Published
2023
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28. Recycling of Printed Multilayer Plastic Packaging Films by Solvent-Targeted Recovery and Precipitation

Author

Sánchez-Rivera, Kevin L., primary, del Carmen Munguía-López, Aurora, additional, Zhou, Panzheng, additional, Cecon, Victor S., additional, Yu, Jiuling, additional, Nelson, Kevin, additional, Miller, Daniel, additional, Grey, Steve, additional, Xu, Zhuo, additional, Bar-Ziv, Ezra, additional, Vorst, Keith L., additional, Curtzwiler, Greg W., additional, Van Lehn, Reid C., additional, Zavala, Victor M., additional, and Huber, George W., additional

Published
2023
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35. Expanding Plastics Recycling Technologies: Chemical Aspects, Technology Status and Challenges

Author

Li, Houqian, primary, Aguirre-Villegas, Horacio A., additional, Allen, Robert D., additional, Bai, Xianglan, additional, Benson, Craig H., additional, Beckham, Gregg T., additional, Bradshaw, Sabrina L., additional, Brown, Jessica L., additional, Brown, Robert C., additional, Sanchez Castillo, Marco Antonio, additional, Cecon, Victor S., additional, Curley, Julia B., additional, Curtzwiler, Greg W., additional, Dong, Son, additional, Gaddameedi, Soumika, additional, Garcia, John E., additional, Hermans, Ive, additional, Kim, Min Soo, additional, Ma, Jiaze, additional, Mark, Lesli O., additional, Mavrikakis, Manos, additional, Olafasakin, Olumide O., additional, Osswald, Tim A., additional, Papanikolaou, Kostas G., additional, Radhakrishnan, Harish, additional, Sánchez-Rivera, Kevin L., additional, Tumu, Khairun N., additional, Van Lehn, Reid C., additional, Vorst, Keith L., additional, Wright, Mark M., additional, Wu, Jiayang, additional, Zavala, Victor M., additional, Zhou, Panzheng, additional, and Huber, George W., additional

Published
2022
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39. Correction: Expanding plastics recycling technologies: chemical aspects, technology status and challenges

Author

Li, Houqian, primary, Aguirre-Villegas, Horacio A., additional, Allen, Robert D., additional, Bai, Xianglan, additional, Benson, Craig H., additional, Beckham, Gregg T., additional, Bradshaw, Sabrina L., additional, Brown, Jessica L., additional, Brown, Robert C., additional, Cecon, Victor S., additional, Curley, Julia B., additional, Curtzwiler, Greg W., additional, Dong, Son, additional, Gaddameedi, Soumika, additional, Estela-García, John E., additional, Hermans, Ive, additional, Kim, Min Soo, additional, Ma, Jiaze, additional, Mark, Lesli O., additional, Mavrikakis, Manos, additional, Olafasakin, Olumide O., additional, Osswald, Tim A., additional, Papanikolaou, Konstantinos G., additional, Radhakrishnan, Harish, additional, Sanchez Castillo, Marco Antonio, additional, Sánchez-Rivera, Kevin L., additional, Tumu, Khairun N., additional, Van Lehn, Reid C., additional, Vorst, Keith L., additional, Wright, Mark M., additional, Wu, Jiayang, additional, Zavala, Victor M., additional, Zhou, Panzheng, additional, and Huber, George W., additional

Published
2022
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45. Reducing Antisolvent Use in the STRAP Process by Enabling a Temperature‐Controlled Polymer Dissolution and Precipitation for the Recycling of Multilayer Plastic Films

Author

Sánchez‐Rivera, Kevin L., primary, Zhou, Panzheng, additional, Kim, Min Soo, additional, González Chávez, Leonardo D., additional, Grey, Steve, additional, Nelson, Kevin, additional, Wang, Shao‐Chun, additional, Hermans, Ive, additional, Zavala, Victor M., additional, Van Lehn, Reid C., additional, and Huber, G. W., additional

Published
2021
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49. Energy landscape for the insertion of amphiphilic nanoparticles into lipid membranes: A computational study

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Van Lehn, Reid C, Alexander-Katz, Alfredo, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Van Lehn, Reid C, and Alexander-Katz, Alfredo

Abstract

© 2019 Van Lehn, Alexander-Katz. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Amphiphilic, monolayer-protected gold nanoparticles (NPs) have been shown to enter cells via a non-endocytic, non-disruptive pathway that could be valuable for biomedical applications. The same NPs were also found to insert into a series of model cell membranes as a precursor to cellular uptake, but the insertion mechanism remains unclear. Previous simulations have demonstrated that an amphiphilic NP can insert into a single leaflet of a planar lipid bilayer, but in this configuration all charged end groups are localized to one side of the bilayer and it is unknown if further insertion is thermodynamically favorable. Here, we use atomistic molecular dynamics simulations to show that an amphiphilic NP can reach the bilayer midplane non-disruptively if charged ligands iteratively “flip” across the bilayer. Ligand flipping is a favorable process that relaxes bilayer curvature, decreases the nonpolar solvent-accessible surface area of the NP monolayer, and increases attractive ligand-lipid electrostatic interactions. Analysis of end group hydration further indicates that iterative ligand flipping can occur on experimentally relevant timescales. Supported by these results, we present a complete energy landscape for the non-disruptive insertion of amphiphilic NPs into lipid bilayers. These findings will help guide the design of NPs to enhance bilayer insertion and non-endocytic cellular uptake, and also provide physical insight into a possible pathway for the translocation of charged biomacromolecules.

Published
2021

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