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Paul M Szlosek

from Sanford, ME
Age ~70
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Also known as:
Paul E Szlosek, Elizabeth Szlosek, Paul K
Phone and address:
24 Patriots Ln UNIT 103, Sanford, ME 04073
Related to:
Bekki SzlosekJoanne Benson, 68Roger Hewitt, 74Edward Szlosek, 66Rebekah Szlosek, 41Donald Szlosek
Connected to:
Marianne Szlyk, 59Cecile Szmajlo, 74Samantha L Szmalc, 38Thomas R Szmanda, 64Brian Szmatula, 55Elizabeth N Szmed, 36Michelle E Szmer, 75Natanela Szmer, 43Ewa M Szmidt, 76Maria J Szmidt, 66

Paul Szlosek Phones & Addresses

  • 24 Patriots Ln UNIT 103, Sanford, ME 04073
  • 305 Cat Mousam Rd, Kennebunk, ME 04043 (207) 985-8492
  • Petaluma, CA
  • Chicopee, MA
  • 305 Cat Mousam Rd, Kennebunk, ME 04043 (207) 251-1330

Work

Position: Professional/Technical

Education

Degree: Associate degree or higher

Resumes

Resumes

Paul Szlosek Photo 1

Paul Szlosek

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Location:
2 Alfred Rd, Kennebunk, ME 04043
Industry:
Plastics
Work:
Corning Incorporated 1984 - 2011
Senior Development Engineer
Education:
University of Massachusetts Lowell
Paul Szlosek Photo 2

Paul Szlosek

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Paul Szlosek Photo 3

Paul Szlosek

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Paul Szlosek Photo 4

Senior Development Engineer At Corning Life Sciences

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Position:
Senior Development Engineer at Corning Life Sciences
Location:
Portland, Maine Area
Industry:
Medical Devices
Work:
Corning Life Sciences
Senior Development Engineer
GTE Sep 1981 - Aug 1984
Product Engineer
Education:
University of Massachusetts at Lowell 1981 - 1985
B.S., Plastic Technology

Publications

Us Patents

Microplates With Uv Permeable Bottom Wells

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US Patent:
RE38214, Aug 12, 2003
Filed:
Jan 12, 2001
Appl. No.:
09/760250
Inventors:
William J. Lacey - North Andover MA
Gregory Mathus - Concord MA
Paul M. Szlosek - Kennebunk ME
Assignee:
Corning Incorporated - Corning NY
International Classification:
B01L 300
US Classification:
422102, 422 99
Abstract:
Microplates and methods for manufacturing microplates. The microplate is designed to allow UV radiation to pass through the bottom wells of the microplate so that the microplate can be used for assaying samples by use of UV absorbance. In one embodiment, the microplate comprises at least first and second wells, each well having a UV permeable bottom. In another embodiment, the microplate comprises a frame having an upper portion and a lower portion contiguous with the upper portion and a sheet disposed between the upper portion and the lower portion and defining the bottom of at least one well of the microplate. One embodiment of the method includes steps of inserting a sheet of UV permeable material into a mold cavity that includes sections shaped to form the sidewalls of the plurality of wells, injecting molten plastic material into the mold cavity, and cooling the plastic material to form the microplate with the plastic material forming the sidewalls of each of the first and second wells and the sheet of UV permeable material forming the bottom of each of the first and second wells. Another embodiment of the method includes providing an upper plate defining sidewalls of at least one well, adhering an intermediate layer to the upper plate and adhering a sheet of UV permeable material to the intermediate layer. A further embodiment of the method includes inserting a sheet of material having at least one hole into a mold cavity, injecting a molten plastic material into the mold cavity and cooling the plastic material to form a microplate.

Substrate Container That Does Not Degrade Substrate Surface

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US Patent:
7191901, Mar 20, 2007
Filed:
Mar 27, 2003
Appl. No.:
10/400205
Inventors:
Paul W. Maxim - Horseheads NY, US
Kevin T. Morris - Hammondsport NY, US
James B. Stamatoff - Painted Post NY, US
Paul M. Szlosek - Kennebunk ME, US
Assignee:
Corning Incorporated - Corning NY
International Classification:
B65D 85/48
US Classification:
206456, 206205, 2065241
Abstract:
Packages and methods for containing slides adapted for the attachment of biomolecules. The containers do not degrade the ability of biomolecules to attach to the surface when the slides are stored or shipped in the container.

Multiwell Plate Having Transparent Well Bottoms And Method For Making The Mulitiwell Plate

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US Patent:
7531140, May 12, 2009
Filed:
Jun 6, 2006
Appl. No.:
11/448368
Inventors:
Paul M. Szlosek - Kennebunk ME, US
Assignee:
Corning Incorporated - Corning NY
International Classification:
B01L 3/00
US Classification:
422102
Abstract:
A multiwell plate is described that is used for assaying samples and is made from a plastic upper plate which forms the sidewalls of one or more wells and a transparent lower plate which forms the bottom walls of the wells. The upper plate and lower plate are attached and bound to one another by a series of rings. Also described herein is a method for making such multiwell plates.

Radio Frequency Label For Multiwell Plates Or Slides

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US Patent:
20020030598, Mar 14, 2002
Filed:
Feb 16, 2001
Appl. No.:
09/785880
Inventors:
Scott Dombrowski - Kennebunkport ME, US
Martin Popoloski - Woburn MA, US
Paul Szlosek - Kennebunk ME, US
Alan Tibbetts - Limington ME, US
International Classification:
G08B013/14
US Classification:
340/572100, 340/540000
Abstract:
A multiwell plate or other substrate for use in performing biological and chemical analysis, the contents of which are identifiable by means of a radio frequency labeling system.

Microplate Manufactured From A Thermally Conductive Material And Methods For Making And Using Such Microplates

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US Patent:
20030170883, Sep 11, 2003
Filed:
Mar 11, 2002
Appl. No.:
10/094762
Inventors:
Gregory Martin - Acton ME, US
Paul Szlosek - Kennebunk ME, US
Assignee:
Corning Incorporated
International Classification:
C12M001/34
US Classification:
435/288400, 435/305200, 435/287200
Abstract:
A microplate that is manufactured from a thermally conductive material and methods for making and using the microplate are described herein. Basically, the microplate has a series of wells formed within a frame that is manufactured from a thermally conductive material which enables the wells to have relatively rigid walls which in turn makes it easier to handle the microplate. The thermally conductive material can be a metal or a mixture of a polymer (e.g., polypropylene, LCP) and one or more thermally conductive additives (e.g., carbon fiber, metal, ceramic). Also described herein is a tube manufactured from a thermally conductive material and methods for making and using the tube.

Cell Culture Device And Methods For Manufacturing And Using The Cell Culture Device

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US Patent:
20090246864, Oct 1, 2009
Filed:
Mar 14, 2008
Appl. No.:
12/075836
Inventors:
Paul M. Szlosek - Kennebunk ME, US
International Classification:
C12M 1/00
B29C 39/00
US Classification:
4352975, 264259, 264478
Abstract:
A cell culture device, a method for manufacturing the cell culture device using an In Mold Labeling (IML) technique, and a method for using the cell culture device are all described herein. The cell culture device is an In Line Molded frame which has a cell growth film permanently bonded thereto. The cell growth film can be a film coated with, for example, three-dimensional randomly oriented electrospun polyamide nanofibers, a hydrogel formulation, (meth)acrylate monomers or polymers, urethane (meth)acrylate monomers or polymers, or epoxide formulation.

Microplates With Uv Permeable Bottom Wells

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US Patent:
58583092, Jan 12, 1999
Filed:
Mar 22, 1996
Appl. No.:
8/621085
Inventors:
Gregory Mathus - Concord MA
Paul M. Szlosek - Kennebunk ME
William J. Lacey - Watertown MA
Assignee:
Corning Incorporated - Corning NY
International Classification:
B01L 300
US Classification:
422102
Abstract:
Microplates and methods for manufacturing microplates. The microplate is designed to allow UV radiation to pass through the bottom wells of the microplate so that the microplate can be used for assaying samples by use of UV absorbance. In one embodiment, the microplate comprises at least first and second wells, each well having a UV permeable bottom. In another embodiment, the microplate comprises a frame having an upper portion and a lower portion contiguous with the upper portion and a sheet disposed between the upper portion and the lower portion and defining the bottom of at least one well of the microplate. One embodiment of the method includes steps of inserting a sheet of UV permeable material into a mold cavity that includes sections shaped to form the sidewalls of the plurality of wells, injecting molten plastic material into the mold cavity, and cooling the plastic material to form the microplate with the plastic material forming the sidewalls of each of the first and second wells and the sheet of UV permeable material forming the bottom of each of the first and second wells. Another embodiment of the method includes providing an upper plate defining sidewalls of at least one well, adhering an intermediate layer to the upper plate and adhering a sheet of UV permeable material to the intermediate layer. A further embodiment of the method includes inserting a sheet of material having at least one hole into a mold cavity, injecting a molten plastic material into the mold cavity and cooling the plastic material to form a microplate.

Microplates Which Prevent Optical Cross-Talk Between Wells

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US Patent:
57594945, Jun 2, 1998
Filed:
Oct 5, 1995
Appl. No.:
8/539421
Inventors:
Paul M. Szlosek - Kennebunk ME
Assignee:
Corning Incorporated
International Classification:
B01L 300
US Classification:
422102
Abstract:
A microplate and a method for manufacturing microplates. The microplate is designed to reduce optical cross-talk during the assaying of samples. The microplate comprises a plurality of wells having light permeable sidewalls, a layer of light permeable material forming a bottom of the wells, and ribs of light impermeable material extending through the layer of light permeable material. The method includes steps of inserting a plate of light permeable material into a mold cavity that includes sections shaped to form the sidewalls of the plurality of wells, injecting molten light impermeable material into the mold cavity, and cooling the light impermeable material to form the microplate with the light impermeable material forming the sidewalls of each of the plurality of wells and the plate of light permeable material forming the bottom wall of each of the plurality of wells.
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Paul M Szlosek from Sanford, ME, age ~70 Get Report