A three-dimensional printed cell for rapid, low-volume spectroelectrochemistry

被引：17

作者：

Brisendine, Joseph M. ^{[1
]}

Mutter, Andrew C. ^{[1
]}

Cerda, Jose F. ^{[2
]}

Koder, Ronald L. ^{[1
,3
,4
,5
,6
]}

机构：

[1] CUNY City Coll, Dept Phys, New York, NY 10031 USA

[2] St Josephs Univ, Dept Chem, Philadelphia, PA 19131 USA

[3] CUNY, Grad Ctr, Grad Program Phys, New York, NY 10016 USA

[4] CUNY, Grad Ctr, Grad Program Chem, New York, NY 10016 USA

[5] CUNY, Grad Ctr, Grad Program Biochem, New York, NY 10016 USA

[6] CUNY, Grad Ctr, Grad Program Biol, New York, NY 10016 USA

来源：

ANALYTICAL BIOCHEMISTRY | 2013年 / 439卷 / 01期

基金：

美国国家科学基金会;

关键词：

Safranine; Spectroelectrochemistry; Reduction potential; 3D printing; CYTOCHROME-C; THIN-LAYER; PROTEIN; COFACTOR;

D O I：

10.1016/j.ab.2013.03.036

中图分类号：

Q5 [生物化学];

学科分类号：

071010 ; 081704 ;

摘要：

We have used three-dimensional (3D) printing technology to create an inexpensive spectroelectrochemical cell insert that fits inside a standard cuvette and can be used with any transmission spectrometer. The cell positions the working, counter, and reference electrodes and has an interior volume of approximately 200 mu l while simultaneously providing a full 1-cm path length for spectroscopic measurements. This method reduces the time required to perform a potentiometric titration on a molecule compared with standard chemical titration methods and achieves complete electrolysis of protein samples within minutes. Thus, the device combines the best aspects of thin-layer cells and standard potentiometry. (C) 2013 Elsevier Inc. All rights reserved.

引用

页码：1 / 3

页数：3

共 50 条

[31] A new, rapid visualization method for detection of ischemic risk volume by three-dimensional echocardiography
Ohazama, CJ
Stetten, G
Fleishman, CE
Ota, T
Lewis, CW
Morris, E
Ryan, T
vonRamm, OT
Kisslo, J
JOURNAL OF THE AMERICAN COLLEGE OF CARDIOLOGY, 1997, 29 (02) : 7227 - 7227
[32] Rapid soils analysis kit for low-volume roads and contingency airfields
Berney, Ernest S., IV
Wahl, Ronald E.
TRANSPORTATION RESEARCH RECORD, 2007, 2 (1989) : 71 - 78
[33] A low-volume flow electrochemical microreactor for rapid and automated process optimization
Rial-Rodriguez, Eduardo
Wagner, Johannes F.
Eggenweiler, Hans-Michael
Fuchss, Thomas
Sommer, Alena
Kappe, C. Oliver
Williams, Jason D.
Cantillo, David
REACTION CHEMISTRY & ENGINEERING, 2023, 9 (01) : 31 - 36
[34] A Low-Cost Three-Dimensional Printed Retractor for Transforaminal Lumbar Interbody Fusion
Encarnacion Ramirez, Manuel de Jesus
Nurmukhametov, Renat
Bernard, Edwin
Peralta, Ismael
Efe, Ibrahim E.
CUREUS JOURNAL OF MEDICAL SCIENCE, 2022, 14 (04)
[35] Automatic three-dimensional detection and volume estimation of low-grade gliomas
Boudrioua, Asma
Aloui, Abdelouahab
Solaiman, Basel
Asli, Larbi
Ben Salem, Douraied
Tliba, Souhil
INTERNATIONAL JOURNAL OF IMAGING SYSTEMS AND TECHNOLOGY, 2021, 31 (03) : 1678 - 1691
[36] Three-dimensional printed anatomical models in scaphoid surgery
ten Berg, Paul W. L.
Dobbe, Johannes G. G.
Streekstra, Geert J.
JOURNAL OF HAND SURGERY-EUROPEAN VOLUME, 2018, 43 (01) : 101 - 102
[37] Three-dimensional printed cardiac fistulae: a case series
Aroney, Nicholas
Markham, Ryan
Putrino, Anthony
Crowhurst, James
Wall, Douglas
Scalia, Gregory
Walters, Darren
EUROPEAN HEART JOURNAL-CASE REPORTS, 2019, 3 (02)
[38] The control of stem cell morphology and differentiation using three-dimensional printed scaffold architecture
Guvendiren, Murat
Fung, Stephanie
Kohn, Joachim
De Maria, Carmelo
Montemurro, Francesca
Vozzi, Giovanni
MRS COMMUNICATIONS, 2017, 7 (03) : 383 - 390
[39] Infinite Approaching Superlubricity by Three-Dimensional Printed Structures
Zhao, Yu
Mei, Hui
Chang, Peng
Chen, Chao
Cheng, Laifei
Dassios, Konstantinos G.
ACS NANO, 2021, 15 (01) : 240 - 257
[40] The control of stem cell morphology and differentiation using three-dimensional printed scaffold architecture
Murat Guvendiren
Stephanie Fung
Joachim Kohn
Carmelo De Maria
Francesca Montemurro
Giovanni Vozzi
MRS Communications, 2017, 7 : 383 - 390

← 1 2 3 4 5 →