Greg Olson, Age 42Burnsville, MN

8276587, Oct 2, 2012

Feb 17, 2009

12/372082

Hai Zhang - Plymouth MN, US
Will Zanto - Blaine MN, US
Qian Shi - Blaine MN, US
Greg Olson - Shoreview MN, US
Phillip Poeschl - Maplewood MN, US
Vincent Majkowski - Maple Grove MN, US
Stuart J. Olstad - Plymouth MN, US

TSI, Incorporated - Shoreview MN

A61M 16/00
A61M 16/14
A61M 15/00

12820621, 12820319, 12820424, 12820425, 12820525, 12820626, 239338

A hand-held, automated qualitative fit tester (QLFT) for establishing gas mask fit integrity. The automated QLFT may be configured to utilize a pressure source in combination with a cartridge and a nebulizer to generate aerosols having size distributions and concentrations that are substantially the same as OSHA-approved manual units. The QLFT may further include a cartridge that contains the aerosol solution used to test mask integrity. The cartridge may be configured to recapture solution that collects on the interior walls of the nebulizer. The automated QLFT may also be equipped with a microprocessor for executing sequences that are in substantive compliance with 29 CFR 1910. 134 and for writing to a data storage device. The automated aspects of the invention can reduce or negate the need for operating personnel to repeatedly and manually actuate a squeeze ball and record results manually, as is required with present OSHA-approved hand-held aerosol generators.

8353867, Jan 15, 2013

May 4, 2004

10/838540

Greg Olson - Elk River MN, US

Boston Scientific Scimed, Inc. - Maple Grove MN

A61M 37/00
A61M 31/00

60410306

Medical devices and methods of making medical devices are described. In some embodiments, a medical device includes a member having a first portion with a first wall thickness, and a second portion with a second wall thickness, wherein the first portion is circumferentially rotated.

8376960, Feb 19, 2013

Jul 27, 2005

11/190983

Greg Olson - Elk River MN, US

Boston Scientific Scimed, Inc. - Maple Grove MN

A61B 5/00

600585, 604 9504

Medical devices capable of having variable stiffness, and related methods, are disclosed. In some embodiments, a medical device includes an elongated member adapted to be inserted into a subject, and an electrorheological fluid carried by the elongated member.

8500797, Aug 6, 2013

May 13, 2008

12/119885

Greg Olson - Elk River MN, US
Michael S. Arney - Minneapolis MN, US
Scott R. Schewe - Eden Prairie MN, US

Boston Scientific Scimed, Inc. - Maple Grove MN

A61F 2/06

623 142

Medical devices and related methods are disclosed. In some embodiments, a method of manufacturing a medical device or a medical device component includes contacting a non-fluid first member and a second member, the first member comprising a first polymer and an alignable material different from the first polymer; aligning the alignable material; and bonding the first and second members together.

2005004, Mar 3, 2005

Sep 2, 2003

10/653123

Greg Olson - Elk River MN, US

Scimed Life Systems, Inc. - Maple Grove MN

B32B003/26
A61N001/30

604021000, 428319300, 428319700, 428315500

A method of forming a medical device or components thereof, including the steps of providing a first component of said medical device which is formed a first material and providing a second polymeric material into a mold cavity to overmold a second component of the medical device over the first component, and wherein the second polymeric material is further injected with a blowing agent to form a foam, and to components and to the medical devices made therefrom.

2005009, May 5, 2005

Nov 4, 2003

10/699694

Greg Olson - Elk River MN, US

A61M025/00

600300000, 604265000, 427002100, 604500000

Nanotube treatments for internal medical devices are provided in the present invention. This may include a medical apparatus sized for insertion into a patient wherein the medical apparatus has a plurality of nanotubes associated with one of its surface. This invention may also include a diagnostic method that comprises inserting a plurality of nanotubes into a body of a patient, positioning the plurality of nanotubes at a target site within the body of the patient, interfacing the plurality of nanotubes with the target site, removing the plurality of nanotubes from the target site, and analyzing the plurality of nanotubes after they have been removed from the target site. This invention may also include a method for manufacturing a medical device sized for insertion into the body. The method comprising providing a medical device and interfacing the medical device with a plurality of nanotubes.

2006023, Oct 19, 2006

Apr 15, 2005

11/106582

Greg Olson - Elk River MN, US

A61L 33/00
B05D 3/00
B05C 5/00

427002100, 118300000

A method of coating a medical device is provided that includes forming a beam of ions of a coating material and focusing said beam using at least one electrostatic lens. The method also includes arranging the medical device within said beam. In the method, the forming of said beam of the coating material may include aerosolizing a solution of the coating material and evaporating a solvent of the solution. The method may include providing an opposite electrostatic charge to the medical device. The method may include fixturing the medical device to allow the coating material to contact about all of a surface of the medical device. The method may include rotating the medical device about an axis perpendicular to said beam. The method may include moving the medical device through the region of the focus of the at least one electrostatic lens and contacting said beam with a portion of an exposed surface of the medical device. A system for coating a medical device is provided. A medical device having a coating applied by a method is provided.

2021033, Oct 28, 2021

Apr 21, 2021

17/237023

- Luxembourg, LU
Greg OLSON - Elk River MN, US

A61B 34/20

A medical device may include a tubular body defining a central longitudinal axis and a lumen, the tubular body including an annular wall having an inner circumferential surface and an outer circumferential surface. The medical device may include a multi-core fiber extending along at least a portion of the length of the tubular body and at least partially disposed in the annular wall thereof. The medical device may include a plurality of single-core fibers extending along at least a portion of the length of the tubular body and defining a central longitudinal axis that is nonparallel to the central longitudinal axis of the tubular body. A medical device may include a multi-core fiber disposed on a top surface of a first layer and extending along at least a portion of the length of the first layer; and a second layer deposited or printed on the first layer.