Abstract

The long term goal of the PI's research is to miniaturize high-throughput screening (HTS) of lipophilic drug candidates in order to make HTS technology widely accessible. There is a well-established need to miniaturize HTS in order to reduce the cost, time, and accessibility of this process. Small molecule microarrays are a promising solution to this problem, yet are currently limited in their ability to deliver sufficien dosages to cells cultured on them in a high-throughput format without cross-contamination. The idea behind this project is to encapsulate lipophilic drug candidates within surface-supported lipid multilayer arrays, culture cells over this array, and screen for drug efficacy in a microarra format. Because lipophilic drug candidates are used, cross contamination due to leakage and diffusion of the drug candidates through the aqueous solution will be minimal. Cationic lipids developed for liposomal formulations will be used to promote cellular uptake from the surface. The suitability of lipid multilayer microarrays for HTS applications will be demonstrated by scale up of the fabrication process, determination of the stability of the arrays, and quantification of cellular uptake from the arrays.
Aim 1 is to scale up the fabrication process used to produce lipid multilayer microarrays by combining established microarray technology with the novel method of lipid multilayer stamping to produce arrays with at least 1000 spots per cm2, which is >100 times the density of a standard 1536 well plate. The quality of the arrays will be determined by fluorescence microscopy and atomic force microscopy.
Aim 2 is to determine the stability of the lipid multilayer microarrays after long-term storage and use in cell culture, to ensure insignificat cross-contamination between spots and accessibility of the technology to other scientists. Stability of the arrays will be assayed in storage and under cell culture conditions by fluorescence microscopy and any leakage of encapsulated compounds will be quantified by HPLC.
Aim 3 is to obtain quantitative dose- response curves from an individual surface by fabricating spots of different multilayer thickness and testing, by means of toxicity assays and live-cell imaging of fluorophores delivered to the cells, of the hypothesis that multilayer thicknes determines the dosage received by the cells. The contribution of the proposed research will enable delivery of lipophilic drugs to cells in a microarray format with up to 200,000 tests on a single titer plate, making HTS widely accessible. The novel aspect of this proposal is to encapsulate lipophilic drug candidates into within lipid multilayer microarrays to allow testing of high dosages without cross-contamination.

Public Health Relevance

The proposed research is relevant to public health because it will result in a biomedical technology that will allow better pharmaceuticals to be developed faster and at lower cost, making them more accessible to the public. Furthermore, development of this technology will enable entirely new possibilities in personalized medicine and point-of-care testing, for example by using cells obtained from an individual patient's biopsy to screen combinations of FDA approved drugs to assist doctors in giving effective prescriptions.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM107172-03
Application #
8848087
Study Section
Enabling Bioanalytical and Imaging Technologies Study Section (EBIT)
Program Officer
Fabian, Miles
Project Start
2013-09-01
Project End
2016-05-31
Budget Start
2015-06-01
Budget End
2016-05-31
Support Year
3
Fiscal Year
2015
Total Cost
Indirect Cost

  Institution

Name
Florida State University
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
790877419
City
Tallahassee
State
FL
Country
United States
Zip Code
32306

  Publications

Kusi-Appiah, Aubrey E; Mastronardi, Melanie L; Qian, Chenxi et al. (2017) Enhanced cellular uptake of size-separated lipophilic silicon nanoparticles. Sci Rep 7:43731
Kumar, Ravi; Urtizberea, Ainhoa; Ghosh, Souvik et al. (2017) Polymer Pen Lithography with Lipids for Large-Area Gradient Patterns. Langmuir 33:8739-8748
Lowry, Troy W; Hariri, Hanaa; Prommapan, Plengchart et al. (2016) Quantification of Protein-Induced Membrane Remodeling Kinetics In Vitro with Lipid Multilayer Gratings. Small 12:506-15
Ghazanfari, Lida; Lenhert, Steven (2016) Screening of Lipid Composition for Scalable Fabrication of Solvent-Free Lipid Microarrays. Front Mater 3:
Vafai, Nicholas; Lowry, Troy W; Wilson, Korey A et al. (2015) Evaporative edge lithography of a liposomal drug microarray for cell migration assays. Nanofabrication 2:34-42
Kusi-Appiah, A E; Lowry, T W; Darrow, E M et al. (2015) Quantitative dose-response curves from subcellular lipid multilayer microarrays. Lab Chip 15:3397-404
Lowry, Troy W; Prommapan, Plengchart; Rainer, Quinn et al. (2015) Lipid Multilayer Grating Arrays Integrated by Nanointaglio for Vapor Sensing by an Optical Nose. Sensors (Basel) 15:20863-72
Lowry, Troy W; Kusi-Appiah, Aubrey; Guan, Jingjiao et al. (2014) Materials Integration by Nanointaglio. Adv Mater Interfaces 1: