David W. Schmidtke

3.4k total citations
76 papers, 2.8k citations indexed

About

David W. Schmidtke is a scholar working on Electrical and Electronic Engineering, Biomedical Engineering and Polymers and Plastics. According to data from OpenAlex, David W. Schmidtke has authored 76 papers receiving a total of 2.8k indexed citations (citations by other indexed papers that have themselves been cited), including 30 papers in Electrical and Electronic Engineering, 20 papers in Biomedical Engineering and 18 papers in Polymers and Plastics. Recurrent topics in David W. Schmidtke's work include Electrochemical sensors and biosensors (28 papers), Conducting polymers and applications (17 papers) and Electrochemical Analysis and Applications (15 papers). David W. Schmidtke is often cited by papers focused on Electrochemical sensors and biosensors (28 papers), Conducting polymers and applications (17 papers) and Electrochemical Analysis and Applications (15 papers). David W. Schmidtke collaborates with scholars based in United States, Sweden and France. David W. Schmidtke's co-authors include Adam Heller, Scott L. Diamond, Daniel T. Glatzhofer, Stephen A. Merchant, Youdan Wang, Pratixa P. Joshi, David P. Hickey, Matthew T. Meredith, Matthew B. Johnson and Benjamin R. Horrocks and has published in prestigious journals such as Proceedings of the National Academy of Sciences, Journal of Biological Chemistry and The Journal of Cell Biology.

In The Last Decade

David W. Schmidtke

75 papers receiving 2.8k citations

Peers

David W. Schmidtke
Mark Kastantin United States
Kosuke Ino Japan
Małgorzata A. Witek United States
Toshio Sasaki Japan
Chun‐Wei Chen United States
Ciro Chiappini United Kingdom
Hsiang‐Chieh Hung United States
M. Jozéfowicz France
Shih-Hsun Chen Taiwan
Chiun‐Jye Yuan Taiwan
Mark Kastantin United States
David W. Schmidtke
Citations per year, relative to David W. Schmidtke David W. Schmidtke (= 1×) peers Mark Kastantin

Countries citing papers authored by David W. Schmidtke

Since Specialization
Citations

This map shows the geographic impact of David W. Schmidtke's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by David W. Schmidtke with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites David W. Schmidtke more than expected).

Fields of papers citing papers by David W. Schmidtke

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by David W. Schmidtke. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by David W. Schmidtke. The network helps show where David W. Schmidtke may publish in the future.

Co-authorship network of co-authors of David W. Schmidtke

This figure shows the co-authorship network connecting the top 25 collaborators of David W. Schmidtke. A scholar is included among the top collaborators of David W. Schmidtke based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with David W. Schmidtke. David W. Schmidtke is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
Varner, Victor D., et al.. (2025). Effect of Decorin and Aligned Collagen Fibril Topography on TGF-β1 Activation of Corneal Keratocytes. Bioengineering. 12(3). 259–259. 1 indexed citations
2.
Hook, Jessica S., et al.. (2024). Quantifying neutrophil extracellular trap release in a combined infection–inflammation NET-array device. Lab on a Chip. 24(3). 615–628. 7 indexed citations
3.
Pandey, Pratima, Changsong Yang, Bing Li, et al.. (2024). Spatiotemporal coordination of actin regulators generates invasive protrusions in cell–cell fusion. Nature Cell Biology. 26(11). 1860–1877. 5 indexed citations
4.
Hernández, Paula, et al.. (2024). Fabrication of Micropatterns of Aligned Collagen Fibrils. Langmuir. 40(5). 2551–2561. 3 indexed citations
5.
Miron-Mendoza, Miguel, et al.. (2023). Effects of Topography and PDGF on the Response of Corneal Keratocytes to Fibronectin-Coated Surfaces. Journal of Functional Biomaterials. 14(4). 217–217. 5 indexed citations
6.
Chen, Jie, Kai‐Chun Lin, Shalini Prasad, & David W. Schmidtke. (2023). Label free impedance based acetylcholinesterase enzymatic biosensors for the detection of acetylcholine. Biosensors and Bioelectronics. 235. 115340–115340. 19 indexed citations
7.
Setiadi, Hendra, et al.. (2021). Oncostatin M: a Potential Biomarker to Predict Infection in Patients with Left Ventricular Assist Devices. ASAIO Journal. 68(8). 1036–1043. 4 indexed citations
8.
Hickey, David P., Nicholas P. Godman, David W. Schmidtke, & Daniel T. Glatzhofer. (2021). Chloroferrocene-mediated laccase bioelectrocatalyst for the rapid reduction of O2. Electrochimica Acta. 383. 138130–138130. 1 indexed citations
9.
Schmidtke, David W., et al.. (2021). Production of erythrocyte microparticles in a sub-hemolytic environment. Journal of Artificial Organs. 24(2). 135–145. 10 indexed citations
10.
Black, Bryan, et al.. (2019). The Effect of Microfluidic Geometry on Myoblast Migration. Micromachines. 10(2). 143–143. 3 indexed citations
11.
Yonet‐Tanyeri, Nihan, et al.. (2019). A high-throughput microfluidic method for fabricating aligned collagen fibrils to study Keratocyte behavior. Biomedical Microdevices. 21(4). 99–99. 9 indexed citations
12.
Fernandez-Perez, Antonio, et al.. (2018). Functional cargo delivery into mouse and human fibroblasts using a versatile microfluidic device. Biomedical Microdevices. 20(3). 52–52. 8 indexed citations
13.
Snyder, Trevor A., et al.. (2018). Effects of Transient Exposure to High Shear on Neutrophil Rolling Behavior. Cellular and Molecular Bioengineering. 11(4). 279–290. 6 indexed citations
14.
Chen, Jie, Rujuta D. Munje, Nicholas P. Godman, et al.. (2017). Improved Performance of Glucose Bioanodes Using Composites of (7,6) Single-Walled Carbon Nanotubes and a Ferrocene-LPEI Redox Polymer. Langmuir. 33(31). 7591–7599. 11 indexed citations
15.
Snyder, Trevor A., et al.. (2017). Constricted microfluidic devices to study the effects of transient high shear exposure on platelets. Biomicrofluidics. 11(6). 64105–64105. 11 indexed citations
16.
Cheng, Tiffany, et al.. (2016). Effects of shear on P-selectin deposition in microfluidic channels. Biomicrofluidics. 10(2). 24128–24128. 7 indexed citations
17.
Harrison, Roger G., Matthias U. Nollert, David W. Schmidtke, & Vassilios I. Sikavitsas. (2006). The Research Proposal in Biomechanical and Biological Engineering Courses.. Chemical Engineering Education. 40(4). 323–326. 1 indexed citations
18.
Ramachandran, Vishwanath, Marcie R. Williams, Tadayuki Yago, David W. Schmidtke, & Rodger P. McEver. (2004). Dynamic alterations of membrane tethers stabilize leukocyte rolling on P-selectin. Proceedings of the National Academy of Sciences. 101(37). 13519–13524. 100 indexed citations
19.
Schmidtke, David W., et al.. (1995). Design and Optimization of a Selective Subcutaneously Implantable Glucose Electrode Based on "Wired" Glucose Oxidase. Analytical Chemistry. 67(7). 1240–1244. 101 indexed citations
20.
Quinn, C. P., David W. Schmidtke, Sten‐Eric Lindquist, et al.. (1994). Design, Characterization, and One-Point in vivo Calibration of a Subcutaneously Implanted Glucose Electrode. Analytical Chemistry. 66(19). 3131–3138. 80 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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