High-Throughput Printing via Microvascular Multinozzle Arrays

被引:133
|
作者
Hansen, Christopher J. [1 ]
Saksena, Rajat [2 ]
Kolesky, David B. [1 ]
Vericella, John J. [1 ]
Kranz, Stephen J. [1 ]
Muldowney, Gregory P. [3 ]
Christensen, Kenneth T. [2 ]
Lewis, Jennifer A. [1 ]
机构
[1] Univ Illinois, Dept Mat Sci & Engn, Urbana, IL 61801 USA
[2] Univ Illinois, Dept Mech Sci & Engn, Urbana, IL 61801 USA
[3] Dow Chem Co USA, Elect Mat, Newark, DE 19713 USA
来源
ADVANCED MATERIALS | 2013年 / 25卷 / 01期
基金
美国国家科学基金会;
关键词
3D printing; multinozzle printheads; additive manufacturing; DIRECT-WRITE METHOD; HYDROGEL SCAFFOLDS; LITHOGRAPHY; ELECTRONICS; COMPOSITES; NETWORKS; INKS; LAW;
D O I
10.1002/adma.201203321
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
Microvascular multinozzle arrays are designed and fabricated for high-throughput printing of functional materials. Ink-flow uniformity within these multigeneration, bifurcating microchannel arrays is characterized by computer modeling and microscopic particle image velocimetry (micro-PIV) measurements. Both single and dual multinozzle printheads are produced to enable rapid printing of multilayered periodic structures over large areas (approximate to 1 m(2)).
引用
收藏
页码:96 / 102
页数:7
相关论文
共 50 条
  • [11] High-throughput printing of combinatorial materials from aerosols
    Zeng, Minxiang
    Du, Yipu
    Jiang, Qiang
    Kempf, Nicholas
    Wei, Chen
    Bimrose, Miles V.
    Tanvir, A. N. M.
    Xu, Hengrui
    Chen, Jiahao
    Kirsch, Dylan J.
    Martin, Joshua
    Wyatt, Brian C.
    Hayashi, Tatsunori
    Saeidi-Javash, Mortaza
    Sakaue, Hirotaka
    Anasori, Babak
    Jin, Lihua
    McMurtrey, Michael D.
    Zhang, Yanliang
    NATURE, 2023, 617 (7960) : 292 - +
  • [12] Printing proteins as microarrays for high-throughput function determination
    MacBeath, G
    Schreiber, SL
    SCIENCE, 2000, 289 (5485) : 1760 - 1763
  • [13] High-throughput printing of combinatorial materials from aerosols
    Minxiang Zeng
    Yipu Du
    Qiang Jiang
    Nicholas Kempf
    Chen Wei
    Miles V. Bimrose
    A. N. M. Tanvir
    Hengrui Xu
    Jiahao Chen
    Dylan J. Kirsch
    Joshua Martin
    Brian C. Wyatt
    Tatsunori Hayashi
    Mortaza Saeidi-Javash
    Hirotaka Sakaue
    Babak Anasori
    Lihua Jin
    Michael D. McMurtrey
    Yanliang Zhang
    Nature, 2023, 617 : 292 - 298
  • [14] High-Throughput Fabrication of Large-Scale Metaholograms via One-step Printing
    Park, Chanwoong
    Kim, Wonjoong
    Kim, Yeseul
    Sung, Hansang
    Park, Jaein
    Song, Hyoin
    Kim, Joohoon
    Oh, Dong Kyo
    Kang, Hyunjung
    Jeon, Nara
    Rho, Junsuk
    Lee, Heon
    ADVANCED OPTICAL MATERIALS, 2024, 12 (09)
  • [15] High-throughput SNP genotyping on universal bead arrays
    Shen, R
    Fan, JB
    Campbell, D
    Chang, WH
    Chen, J
    Doucet, D
    Yeakley, J
    Bibikova, M
    Garcia, EW
    McBride, C
    Steemers, F
    Garcia, F
    Kermani, BG
    Gunderson, K
    Oliphant, A
    MUTATION RESEARCH-FUNDAMENTAL AND MOLECULAR MECHANISMS OF MUTAGENESIS, 2005, 573 (1-2) : 70 - 82
  • [16] Microbioreactor arrays with parametric control for high-throughput experimentation
    Maharbiz, MM
    Holtz, WJ
    Howe, RT
    Keasling, JD
    BIOTECHNOLOGY AND BIOENGINEERING, 2004, 85 (04) : 376 - 381
  • [17] High-throughput gene silencing using cell arrays
    Dominique Vanhecke
    Michal Janitz
    Oncogene, 2004, 23 : 8353 - 8358
  • [18] Stamped arrays of membrane proteins for high-throughput applications
    Majd, Sheereen
    Capone, Ricardo
    Mayer, Michael
    BIOPHYSICAL JOURNAL, 2007, : 5A - 5A
  • [19] Competitive assay formats for high-throughput affinity arrays
    Barry, R
    Diggle, T
    Terrett, J
    Soloviev, M
    JOURNAL OF BIOMOLECULAR SCREENING, 2003, 8 (03) : 257 - 263
  • [20] High-throughput protein arrays:: prospects for molecular diagnostics
    Walter, G
    Büssow, K
    Lueking, A
    Glökler, J
    TRENDS IN MOLECULAR MEDICINE, 2002, 8 (06) : 250 - 253
12345