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Cullen R Buie

from Cambridge, MA
Age ~43
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Also known as:
Collen R Buie, Clinton Buie, Richard Buie Cullen, Tanya Silva
Related to:
James Richard Buie, 49
Connected to:
Alisha Buie, 38Alpha J Buie, 68Anita M Buie, 79Antoine D Buie, 37Calvin Buie, 39Carolyn Buie, 64Dakota C Buie, 28Daniel L Buie, 71Delinda S Buie, 73Felicity Buie, 38

Cullen Buie Phones & Addresses

  • Cambridge, MA
  • Somerville, MA
  • Stanford, CA
  • Hayward, CA
  • 3555 Lytle Rd, Beachwood, OH 44122 (216) 283-0481
  • Shaker Heights, OH
  • Columbus, OH

Resumes

Resumes

Cullen Buie Photo 1

Co-Founder

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Location:
103 Orchard St, Somerville, MA 02144
Industry:
Mechanical Or Industrial Engineering
Work:
Kytopen Corp
Co-Founder
Massachusetts Institute of Technology (Mit)
Associate Professor
Massachusetts Institute of Technology (Mit) Nov 2009 - Jun 2015
Assistant Professor
Uc Berkeley Oct 2008 - Oct 2009
President's Postdoctoral Fellow
The Dow Chemical Company Jun 2002 - Sep 2002
Commercial Development Intern
Education:
Stanford University 2005 - 2009
Doctorates, Doctor of Philosophy, Mechanical Engineering Stanford University 2003 - 2005
Master of Science, Masters, Mechanical Engineering The Ohio State University 1999 - 2003
Bachelors, Bachelor of Science, Mechanical Engineering
Skills:
Fluid Mechanics
Fuel Cells
Matlab
Electrochemistry
Engineering
Simulations
Heat Transfer
Research
Data Analysis
Teaching
Mathematical Modeling
Project Management
Experimentation
Labview
Design of Experiments
Thermodynamics
Fluid Dynamics
Supervising Others
Cullen Buie Photo 2

Cullen Buie

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Publications

Us Patents

Fuel Cell With Electroosmotic Pump

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US Patent:
20060029851, Feb 9, 2006
Filed:
Aug 4, 2004
Appl. No.:
10/912527
Inventors:
Juan Santiago - Fremont CA, US
Jonathan Posner - Menlo Park CA, US
Friedrich Prinz - Woodside CA, US
Tibor Fabian - Menlo Park CA, US
John Eaton - Stanford CA, US
Suk-Won Cha - Stanford CA, US
Cullen Buie - Stanford CA, US
Hideaki Tsuru - Nerima-ku, JP
Jun Sasahara - Kawagoe-shi, JP
Tadahiro Kubota - Asaka-shi, JP
Yuji Saito - Palo Alto CA, US
International Classification:
H01M 8/04
H01M 8/10
US Classification:
429030000, 429034000, 429022000, 429013000
Abstract:
Water flooding at the cathode of a fuel cell is a common problem in fuel cells. By integrating an electroosmotic (EO) pump to remove product water from the cathode area, fuel cell power can be increased. Integration of EO pumps transforms the designs of air channel and air breathing cathodes, reducing air pumping power loads and increasing oxidant transport. Hydration of gas streams, management of liquid reactants, and oxidant delivery can also be accomplished with integrated electroosmotic pumps. Electroosmotic pumps have no moving parts, can be integrated as a layer of the fuel cell, and scale with centimeter to micron scale fuel cells.

Electrophoretic-Deposited Surfaces

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US Patent:
20120211365, Aug 23, 2012
Filed:
Feb 22, 2012
Appl. No.:
13/402126
Inventors:
Young Soo Joung - Cambridge MA, US
Cullen Richard Buie - Cambridge MA, US
Assignee:
Massachusetts Institute of Technology - Cambridge MA
International Classification:
C25D 15/00
US Classification:
204473, 204471, 204472, 204474, 204622
Abstract:
A method of altering a property of a surface includes suspending a plurality of low surface energy particles in a solvent, agglomerating the suspension of particles, and subjecting the suspension of particle agglomerates to electrophoretic deposition onto a substrate for a predetermined time. The altered surface may be superhydrophilic or superhydrophobic.

Methods For Electro-Mechanical Transfection

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US Patent:
20220347468, Nov 3, 2022
Filed:
Apr 27, 2022
Appl. No.:
17/731112
Inventors:
- Cambridge MA, US
Cullen BUIE - Cambridge MA, US
Ross BEIGHLEY - Cambridge MA, US
James HEMPHILL - Medford MA, US
Jessica SIDO - Alton IL, US
Bethany GRANT - Scituate MA, US
International Classification:
A61N 1/32
C12M 1/42
C12N 13/00
Abstract:
Methods, devices, systems, and kits for electro-mechanical cell transfection are provided. A device includes a first electrode, a second electrode, and an active zone therebetween where an electrical potential difference applied to the first and second electrodes generates an electric field in the active zone sufficient to transfect at least a subset of the cells flowing in the active zone.

Devices, Systems, And Kits For Electro-Mechanical Delivery And Methods Of Use Thereof

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US Patent:
20220243164, Aug 4, 2022
Filed:
Jul 2, 2020
Appl. No.:
17/624535
Inventors:
- Cambridge MA, US
Jessica SIDO - Alton IL, US
James HEMPHILL - Medford MA, US
Harrison BRALOWER - Somerville MA, US
Ross BEIGHLEY - Cambridge MA, US
Cullen BUIE - Cambridge MA, US
Bethany GRANT - Scituate MA, US
International Classification:
C12M 1/42
C12N 13/00
C12N 15/87
C12N 5/0783
C12N 5/0786
Abstract:
Devices, systems, and kits for cell transfection are provided. A device includes a first electrode, a second electrode, and an electroporation zone therebetween where an electrical potential difference applied to the first and second electrodes generates an electric field in the electroporation zone sufficient to transfect at least a subset of the cells in the flow path. Methods of introducing a composition into at least a portion of a plurality of cells using the devices, systems, and kits of the invention are also provided.

Fabrication-Free Microfluidic Device For Scalable, High-Volume Bacterial Electroporation

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US Patent:
20230109468, Apr 6, 2023
Filed:
Sep 27, 2022
Appl. No.:
17/935844
Inventors:
- Cambridge MA, US
Cullen Richard Buie - Cambridge MA, US
Sijie Chen - Cambridge MA, US
International Classification:
C12M 1/42
C12N 13/00
C12N 15/87
C12M 1/00
Abstract:
A disposable, fabrication-free, high-volume electroporation device may process cell samples of large volume without compromising transformation efficiency and cell viability, while precipitously reducing the entire processing time and effort. An embodiment includes at least two hollow, tubular conductive elements and an insulating structure, defining a channel, that fluidically couples the at least two conductive elements to define an electroporation flow path in the channel for flow-through electroporation. The high-volume electroporation device can be an alternative to cuvettes for typical volume electroporation, but can also be an indispensable tool to process large volume samples for applications, such as creation of modified sample libraries.

Electrophoretic-Deposited Surfaces

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US Patent:
20150376811, Dec 31, 2015
Filed:
Aug 4, 2015
Appl. No.:
14/817357
Inventors:
- Cambridge MA, US
Cullen Richard BUIE - Cambridge MA, US
Assignee:
MASSACHUSETTS INSTITUTE OF TECHNOLOGY - Cambridge MA
International Classification:
C25D 13/02
C25D 13/12
Abstract:
A method of altering a property of a surface includes suspending a plurality of low surface energy particles in a solvent, agglomerating the suspension of particles, and subjecting the suspension of particle agglomerates to electrophoretic deposition onto a substrate for a predetermined time. The altered surface may be superhydrophilic or superhydrophobic.

Battery With Heterogeneous Flow-Through Porous Electrodes

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US Patent:
20150099199, Apr 9, 2015
Filed:
Oct 2, 2014
Appl. No.:
14/504539
Inventors:
- Cambridge MA, US
William Allan Braff - Cambridge MA, US
Cullen Richard Buie - Cambridge MA, US
Matthew Suss - Cambridge MA, US
Laura M. Gilson - Cambridge MA, US
Kameron Confortl - Cambridge MA, US
Assignee:
Massachusetts Institute of Technology - Cambridge MA
International Classification:
H01M 8/18
H01M 8/08
H01M 8/20
H01M 8/10
US Classification:
429409, 429498, 429495, 429492, 429500, 429418
Abstract:
The invention discloses general apparatus and methods for electrochemical energy conversion and storage via a membraneless laminar flow battery. In a preferred embodiment, the battery includes a flow-through porous anode for receiving a fuel and a porous electrolyte channel for transporting an electrolyte adjacent to the porous anode; a flow-through porous cathode is provided for transporting an oxidant; and a porous dispersion blocker is disposed between the electrolyte channel and the porous cathode, which inhibits convective mixing while allowing molecular diffusion and mean flow. Pore structure properties are selected for tuning convective dispersion, conductivity or other macroscopic properties. Specific materials, reactants, fabrication methods, and operation methods are disclosed to achieve stable charge/discharge cycles and to optimize power density and energy density.

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This Is Not Available 013366

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This book is not available.
Author

Cullen Richard Buie

Binding

Paperback

Pages

158

Publisher

ProQuest, UMI Dissertation Publishing

ISBN #

124358033X

EAN Code

9781243580337

ISBN #

1

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Cullen R Buie from Cambridge, MA, age ~43 Get Report