Andrew J. Bohl scite author profile

Andrew J. Bohl

4Publications

39Citation Statements Received

83Citation Statements Given

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124

Affiliations

Drexel University

Publications

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Design and microfabrication of a high-aspect-ratio PDMS microbeam array for parallel nanonewton force measurement and protein printing

Sasoglu

Bohl

Layton

2007

J. Micromech. Microeng.

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Cell and protein mechanics has applications ranging from cellular development to tissue engineering. Techniques such as magnetic tweezers, optic tweezers and atomic force microscopy have been used to measure cell deformation forces of the order of piconewtons to nanonewtons. In this study, an array of polymeric polydimethylsiloxane (PDMS) microbeams with diameters of 10–40 µm and lengths of 118 µm was fabricated from Sylgard® with curing agent concentrations ranging from 5% to 20%. The resulting spring constants were 100–300 nN µm−1. The elastic modulus of PDMS was determined experimentally at different curing agent concentrations and found to be 346 kPa to 704 kPa in a millimeter-scale array and ∼1 MPa in a microbeam array. Additionally, the microbeam array was used to print laminin for the purpose of cell adhesion. Linear and nonlinear finite element analyses are presented and compared to the closed-from solution. The highly compliant, transparent, biocompatible PDMS may offer a method for more rapid throughput in cell and protein mechanics force measurement experiments with sensitivities necessary for highly compliant structures such as axons.

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Parallel force measurement with a polymeric microbeam array using an optical microscope and micromanipulator

Sasoglu

Bohl

Allen

et al. 2009

Computer Methods and Programs in Biomedicine

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Microfabrication procedure of PDMS microbeam array using photolithography for laminin printing and piconewton force transduction on axons

Sasoglu¹,

Bohl²,

Layton

2006

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The purpose of this paper is to introduce our design for transducing forces on the order of tens of piconewtons by optically measuring deflection of a microfabricated beam tip as it pulls on an array of flexible structures such as axons in an array of laminin-printed neurons. To achieve this we have designed polymeric beams with spring constants on the order of 10 pN/microm. We have fabricated circular microbeams with Sylgard polydimethylsiloxane (PDMS). The elastic modulus of PDMS was determined experimentally using a microscale and a micrometer at different concentrations of curing agent and base agent and found to be on the order of 100 kPa. The designed geometry is a 100x100 tapered microcone array with each beam having a length of 100 microm, and a base diameter of 10 microm. A SU-8 negative photoresist is etched using photolithography and used as a mold for PDMS soft lithography. PDMS was injected into the mold and the array peeled from the mold.

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Microfabrication procedure of PDMS microbeam array using photolithography for laminin printing and piconewton force transduction on axons

Sasoglu¹,

Bohl²,

Layton

2006

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The purpose of this paper is to introduce our design for transducing forces on the order of tens of piconewtons by optically measuring deflection of a microfabricated beam tip as it pulls on an array of flexible structures such as axons in an array of lamininprinted neurons. To achieve this we have designed polymeric beams with spring constants on the order of 10pN/ m. We have fabricated circular microbeams with Sylgard® polydimethylsiloxane (PDMS). The elastic modulus of PDMS was determined experimentally using a microscale and a micrometer at different concentrations of curing agent and base agent and found to be on the order of 100kPa. The designed geometry is a 100x100 tapered microcone array with each beam having a length of 100μm, and a base diameter of 10 μm. A SU-8 negative photoresist is etched using photolithography and used as a mold for PDMS soft lithography. PDMS was injected into the mold and the array peeled from the mold.

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Andrew J. Bohl

Design and microfabrication of a high-aspect-ratio PDMS microbeam array for parallel nanonewton force measurement and protein printing

Parallel force measurement with a polymeric microbeam array using an optical microscope and micromanipulator

Microfabrication procedure of PDMS microbeam array using photolithography for laminin printing and piconewton force transduction on axons

Microfabrication procedure of PDMS microbeam array using photolithography for laminin printing and piconewton force transduction on axons

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