Stephanie Lynne Golmon

20230001054, Jan 5, 2023

Jun 30, 2022

17/855081

- Cambridge MA, US
David J. Carter - Concord MA, US
Corin Williams - Framingham MA, US
Stephanie Lynne Golmon - Arlington MA, US

A61L 27/50
A61L 27/54

A biocompatible adhesive is disclosed. The biocompatible adhesive includes a substrate and a plurality of micro-scale elements extending from a surface of the substrate having a length selected to puncture a layer of a target tissue or target material. At least some of the micro-scale elements include at least one protrusion dimensioned to anchor the biocompatible adhesive to the target tissue or target material. A medical device assembly is also disclosed. The medical device assembly includes the biocompatible adhesive coupled to a surface of a component of the medical device assembly and positioned to attach the medical device assembly to the target tissue or target material. A method of facilitating attachment of a medical device assembly to a target tissue is also disclosed. A method of facilitating treatment of a wound is also disclosed.

20210353443, Nov 18, 2021

Aug 10, 2018

16/637664

- Cambridge MA, US
Stephanie Lynne Golmon - Arlington MA, US
Jonathan R. Coppeta - Windham NH, US
Jesse M. Carr - Cambridge MA, US
Corin Williams - Framingham MA, US

A61F 2/89
A61F 2/24

According to various aspects and embodiments, a growth adaptive expandable stent is provided. The expandable stent includes a stent structure having a cylindrical shape that is self-expanding in a radial direction and includes a plurality of cylindrical rings disposed along a longitudinal axis of the stent structure. The stent structure is configured to exert a continuous outward radial force over time when implanted such that a diameter of the stent structure expands from a first value to a second value that is at least about 1.5 times the first value.

20200386803, Dec 10, 2020

Aug 25, 2020

17/001899

- Cambridge MA, US
Stephanie Lynne Golmon - Arlington MA, US
Paul A. Ward - Dedham MA, US
William D. Sawyer - Littleton MA, US
Marc Steven Weinberg - Needham MA, US
John J. Le Blanc - North Andover MA, US
Louis Kratchman - Quincy MA, US
Daniel K. Freeman - Reading MA, US
Amy Duwel - Cambridge MA, US
Max Lindsay Turnquist - Somerville MA, US
William A. Lenk - Cambridge MA, US

G01R 29/12
G01R 1/04
G01R 33/12
G01R 29/08
G01R 27/26
A61B 5/04
A61B 5/0476
G01R 29/10

Aspects are generally directed to a compact and low-noise electric field detector, methods of operation, and methods of production thereof. In one example, an electric field detector includes a proof mass, a source of concentrated charge coupled to the proof mass, and a substrate having a substrate offset space defined therein, the proof mass being suspended above the substrate offset space. The electric field detector further includes a sense electrode disposed on the substrate within the substrate offset space and proximate the proof mass, the sense electrode being configured to measure a change in capacitance relative to the proof mass from movement of the proof mass in response to a received electric field at the source of concentrated charge. The electric field detector includes a control circuit coupled to the sense electrode and configured to determine a characteristic of the electric field based on the measured change in capacitance.

20200289013, Sep 17, 2020

Mar 16, 2020

16/819705

- Cambridge MA, US
Jesse J. Wheeler - Revere MA, US
Stephanie Lynne Golmon - Arlington MA, US

A61B 5/0408
A61B 5/0492
A61B 5/00

According to various aspects, a sensor system is provided comprising a first substrate configured to be coupled to a user, an electric field detector to detect a user electric field and comprising a second substrate, a proof mass positioned above the second substrate, one or more electrodes coupled to the second substrate, and a control circuit coupled to the one or more electrodes, the control circuit being configured to determine a change in capacitance between the proof mass and each electrode responsive to torsional movement of the proof mass responsive to the electric field, and a controller coupled to the first substrate and being configured to receive, from the detector, information indicative of each change in capacitance between the proof mass and each electrode, and determine, based on the information, characteristics of the electric field in at least two dimensions.

20200257111, Aug 13, 2020

Feb 7, 2020

16/785022

- Cambridge MA, US
Adam F. Kelsey - Cambridge MA, US
David A. Landis - Palm Harbor FL, US
Stephanie L. Golmon - Arlington MA, US
Buddy Clemmer - Burlington MA, US
Juha-Pekka Laine - Boston MA, US

G02B 27/00
G02B 17/06
G02B 27/10
G02B 27/14

A multi channel beamsplitter system operating over a wide spectral band has high optical performance despite the fact that the incoming and/or exiting light is not collimated and its material is dispersive. This is achieved using wavefront compensators that are matched to the curvature of the wavefronts of the incoming and/or exiting light.

20200076006, Mar 5, 2020

Oct 3, 2019

16/592621

- Marlborough MA, US
Hari P. Nayar - Woburn MA, US
Alex T. Vai - Sudbury MA, US
Tom Kinney - Boston MA, US
Sean Theriault - Boston MA, US
Garrett Lau - Cambridge MA, US
Zachary T. Modest - Jamaica Plain MA, US
Stephanie L. Golmon - Arlington MA, US

H01M 10/39
H01M 2/18
H01M 2/02
H01M 4/134
H01M 4/38

Provided herein are energy storage devices. In some cases, the energy storage devices are capable of being transported on a vehicle and storing a large amount of energy. An energy storage device is provided comprising at least one liquid metal electrode, an energy storage capacity of at least about 1 MWh and a response time less than or equal to about 100 milliseconds (ms).

20200005097, Jan 2, 2020

Jun 27, 2019

16/454998

- Cambridge MA, US
Adam Kelsey - Cambridge MA, US
Paul Aaron Bohn - Huntsville AL, US
Stephanie L. Golmon - Arlington MA, US
Francis J. Rogomentich - Wilmington MA, US
Juha-Pekka Laine - Boston MA, US
Buddy A. Clemmer - Burlington MA, US
David A. Landis - Palm Harbor FL, US

G06K 9/62
G01S 13/86
G01S 17/88

A potentially small, gimballed, multi-sensor system employs a shared aperture for at least some of the image sensors. Applications include intelligence, surveillance, target acquisition and reconnaissance (ISTAR), and guiding autonomous vehicles. The system can actively blend images from multiple spectral bands for clarity and interpretability, provide remote identification of objects and material, provide anomaly detection, control lasers and opto-mechanics for image quality, and use shared aperture using folded optics.

20180292470, Oct 11, 2018

Apr 3, 2018

15/944234

- Cambridge MA, US
Stephanie Lynne Golmon - Arlington MA, US
Paul A. Ward - Dedham MA, US
William D. Sawyer - Littleton MA, US
Marc S. Weinberg - Needham MA, US
John J. LeBlanc - North Andover MA, US
Louis Kratchman - Quincy MA, US
Daniel Freeman - Reading MA, US
Amy Duwel - Cambridge MA, US
Max Lindsay Turnquist - Somerville MA, US
William A. Lenk - Cambridge MA, US

G01R 33/00
G01R 1/04
A61B 5/04
G01R 33/12

Aspects are generally directed to a compact and low-noise magnetic field detector, methods of operation, and methods of production thereof. In one example, a magnetic field detector includes a proof mass, a magnetic dipole source coupled to the proof mass, and a substrate having a substrate offset space defined therein, the proof mass being suspended above the substrate offset space. The magnetic field detector further includes a sense electrode disposed on the substrate within the substrate offset space and positioned proximate the proof mass, the sense electrode being configured to measure a change in capacitance relative to the proof mass from movement of the proof mass in response to a received magnetic field at the magnetic dipole source. The magnetic field detector includes a control circuit coupled to the sense electrode and configured to determine a characteristic of the magnetic field based on the measured change in capacitance.