Theresa M. Reineke
Affiliations: | Chemistry | University of Minnesota, Twin Cities, Minneapolis, MN |
Area:
Materials Chemistry; Chemical Biology; Polymer ChemistryWebsite:
http://www.chem.umn.edu/directory/faculty.lasso?serial=3361Google:
"Theresa M. Reineke"Bio:
http://www.reinekegroup.org/dr-reineke
Mean distance: 8.36
Parents
Sign in to add mentor| Michael O'Keeffe | grad student | 2000 | University of Michigan | |
| (Metal -organic porous frameworks designed from zinc(II), terbium(III), europium(III), and organic carboxylate building blocks.) | ||||
| Omar M. Yaghi | grad student | 2000 | University of Michigan | |
| (Metal -organic porous frameworks designed from zinc(II), terbium(III), europium(III), and organic carboxylate building blocks.) | ||||
| Mark E. Davis | post-doc | 2000-2002 | Caltech | |
Children
Sign in to add trainee| Jeffrey M. Ting | grad student | 2011-2016 | UMN |
| Mitra Ganewatta | post-doc | 2017- | UMN |
| Ramya Kumar | post-doc | 2018-2021 | UMN |
BETA: Related publications
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Publications
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| Roy P, Kreofsky NW, Santa Chalarca CF, et al. (2025) Binary Copolymer Blending Enhances pDNA Delivery Performance and Colloidal Shelf Stability of Quinine-Based Polyplexes. Bioconjugate Chemistry |
| Kreofsky NW, Roy P, Reineke TM. (2024) pH-Responsive Micelles Containing Quinine Functionalities Enhance Intracellular Gene Delivery and Expression. Bioconjugate Chemistry |
| Roy P, Kreofsky NW, Reineke TM. (2024) Quinine-Based Polymers Are Versatile and Effective Vehicles for Intracellular pDNA, mRNA, and Cas9 Protein Delivery. Biomacromolecules |
| Leyden MC, Oviedo F, Saxena S, et al. (2024) Synergistic Polymer Blending Informs Efficient Terpolymer Design and Machine Learning Discerns Performance Trends for pDNA Delivery. Bioconjugate Chemistry |
| Dalal RJ, Oviedo F, Leyden MC, et al. (2024) Polymer design SHAP and Bayesian machine learning optimizes pDNA and CRISPR ribonucleoprotein delivery. Chemical Science. 15: 7219-7228 |
| Barr KE, Ohnsorg ML, Liberman L, et al. (2024) Drug-Polymer Nanodroplet Formation and Morphology Drive Solubility Enhancement of GDC-0810. Bioconjugate Chemistry. 35: 499-516 |
| Kreofsky NW, Roy P, Brown ME, et al. (2023) Cinchona Alkaloid Polymers Demonstrate Highly Efficient Gene Delivery Dependent on Stereochemistry, Methoxy Substitution, and Length. Biomacromolecules. 25: 486-501 |
| Lembke HK, Espinasse A, Hanson MG, et al. (2023) Cationic Polymers Enable Internalization of Negatively Charged Chemical Probes into Bacteria. Acs Chemical Biology. 18: 2063-2072 |
| Roy P, Kreofsky NW, Brown ME, et al. (2023) Enhancing pDNA Delivery with Hydroquinine Polymers by Modulating Structure and Composition. Jacs Au. 3: 1876-1889 |
| Porwal MK, Ellison CJ, Reineke TM. (2023) Biobased Copolymers via Cationic Ring-Opening Copolymerization of Levoglucosan Derivatives and ε-Caprolactone. Acs Macro Letters. 935-942 |