Glass micropipettes are versatile probing tools for performing micro- and nano-manipulation tasks. This paper presents the design and development of an automated pipette puller system for fabrication of glass micropipettes. The pipette puller employs a new strategy for fabrication of micropipettes that enables achieving independent control of their taper, tip diameter, and bend-angle, and also facilitates theoretical derivation of simple, approximate relationships between the pipette shape and the pulling parameters. Subsequently, the design and fabrication of the pipette puller is described, which include that of the pipette heating system, the mechanical motion stages, and the control electronics of the pipette puller. The fabricated pipette puller is experimentally evaluated to demonstrate control of the taper, tip diameter, and the bend-angle of the micropipette. Further, the dependence of the taper and tip diameter on the pulling parameters is evaluated and is shown to be in alignment with the proposed theoretical relationships.
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May 2014
Research Article|
May 09 2014
An automated pipette puller for fabrication of glass micropipettes
R. Tamizhanban;
R. Tamizhanban
a)
Department of Instrumentation and Applied Physics,
Indian Institute of Science
, Bangalore 560012, India
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K. R. Sreejith;
K. R. Sreejith
a)
Department of Instrumentation and Applied Physics,
Indian Institute of Science
, Bangalore 560012, India
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G. R. Jayanth
G. R. Jayanth
Department of Instrumentation and Applied Physics,
Indian Institute of Science
, Bangalore 560012, India
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a)
R. Tamizhanban and K. R. Sreejith contributed equally to this work.
Rev. Sci. Instrum. 85, 055105 (2014)
Article history
Received:
March 05 2014
Accepted:
April 20 2014
Citation
R. Tamizhanban, K. R. Sreejith, G. R. Jayanth; An automated pipette puller for fabrication of glass micropipettes. Rev. Sci. Instrum. 1 May 2014; 85 (5): 055105. https://doi.org/10.1063/1.4874316
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