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Stephen E Saddow

from Tampa, FL
Age ~63
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Also known as:
Stephen Edward Saddow, Stephen B Saddow, Stephen E Dackson, Donald Leppla
Phone and address:
16611 Lake Heather Dr, Tampa, FL 33618
(813) 962-2220
Related to:
Eileen M Mackinnon, 98Michael Angelo, 34Vaine A Saddow, 44Karen L Saddow, 58
Connected to:
Cynthia M Saddy, 54George L Saddy, 39Troy A Saddy, 39Belle Sade, 36Carla J Sade, 60Cortez Sade, 40Kalvin M Sade, 50Kim M Sade, 67Lisa M Sade, 35Lynn E Sade, 67

Stephen Saddow Phones & Addresses

  • 16611 Lake Heather Dr, Tampa, FL 33618 (813) 962-2220
  • 11311 Ola Ave, Tampa, FL 33612
  • Land O Lakes, FL
  • 15002 Lakeside Cove Ct, Odessa, FL 33556 (813) 920-1058
  • Laurel, MD
  • Mississippi State, MS
  • Starkville, MS
  • Cedar Knolls, NJ

Work

Company: University of south florida Jul 2001 Position: Professor

Education

Degree: Doctor of Philosophy (PhD) School / High School: University of Maryland College Park 1989 to 1993 Specialities: Electrical Engieering

Skills

Nanotechnology • Materials Science • Afm • Characterization • Thin Films • Physics • Mems • Scanning Electron Microscopy • Nanomaterials • Experimentation • Microfabrication • Science • Semiconductors • R&D • Microscopy • Sensors • Sputtering • Biomedical Engineering • Optical Microscopy • Optoelectronics • Surface Chemistry • Xps • Applied Physics • Biomaterials • Biophysics • Electron Microscopy • Chemistry • Metrology • Nanoparticles

Languages

Italian

Interests

Children • Education • Environment • Poverty Alleviation • Science and Technology • Health

Industries

Higher Education

Resumes

Resumes

Stephen Saddow Photo 1

Professor

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Location:
Tampa, FL
Industry:
Higher Education
Work:
University of South Florida since Jul 2001
Professor
US Army Research Laboratory 1988 - 1996
Electronics Engineer
Education:
University of Maryland College Park 1989 - 1993
Doctor of Philosophy (PhD), Electrical Engieering
Skills:
Nanotechnology
Materials Science
Afm
Characterization
Thin Films
Physics
Mems
Scanning Electron Microscopy
Nanomaterials
Experimentation
Microfabrication
Science
Semiconductors
R&D
Microscopy
Sensors
Sputtering
Biomedical Engineering
Optical Microscopy
Optoelectronics
Surface Chemistry
Xps
Applied Physics
Biomaterials
Biophysics
Electron Microscopy
Chemistry
Metrology
Nanoparticles
Interests:
Children
Education
Environment
Poverty Alleviation
Science and Technology
Health
Languages:
Italian

Business Records

Name / Title
Company / Classification
Phones & Addresses
Stephen Ephd Saddow
Managing
SIC BIOTECHNOLOGY LLC
819 Ambassador Loop, Tampa, FL 33613
16602 Palm Royal Dr APT 1529, Tampa, FL 33647

Publications

Us Patents

Noncontact Anhysteric Curve Plotter And Static Field To Time-Varying Hysteresisgraph With Integrated Temperature Chamber

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US Patent:
8274278, Sep 25, 2012
Filed:
Dec 10, 2009
Appl. No.:
12/635012
Inventors:
Jeremy Walker - Delray Beach FL, US
Stephen E Saddow - Tampa FL, US
Assignee:
University of South Florida - Tampa FL
International Classification:
G01N 27/72
G01R 33/12
US Classification:
324239, 324260, 324228, 324234, 324233, 324204, 324236, 324237, 324238, 324240, 324241, 323355, 374 45
Abstract:
An automated, non-destructive anhysteretic magnetization characterization method for studying and modeling soft magnetic materials. This measurement method employs a “reading-waveform” that allows multiple points of reference to be established in tracing out the B waveform. In using the reference values from this waveform, the components of B that cannot be measured directly may be calculated with precision. In turn, the initial magnitude of the B waveform is identified as the unknown component of the anhysteretic state. The processes can be repeated for different values of static fields as well as a function of temperature to produce a family of anhysteretic magnetization curves. The core characterization was performed without physically altering the core, so that the true anhysteretic magnetization curve, and the true B-H loop under applied bias H, is measured.

Cubic Silicon Carbide Implantable Neural Prosthetic

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US Patent:
20120232631, Sep 13, 2012
Filed:
May 24, 2012
Appl. No.:
13/479631
Inventors:
Christopher Leroy Frewin - Tampa FL, US
Stephen E. Saddow - Odessa FL, US
Edwin Weeber - Apollo Beach FL, US
Assignee:
University of South Florida - Tampa FL
International Classification:
A61N 1/05
H01R 43/00
US Classification:
607116, 29868
Abstract:
An implantable neuronal prosthetic and method of manufacture thereof includes at least one elongated electrode shank adapted for arrangement in the brain having at least one electrode contact disposed on its surface and arranged to electrically couple with said brain. The at least one elongated electrode shank is formed form a single crystal cubic silicon carbide. An insulation layer of amorphous, polycrystalline, or single crystal silicon carbide is disposed over the elongated electrode shank; the insulation layer of amorphous, polycrystalline, or single crystal silicon carbide is removed from the at least one electrode contact. Signal control electronics are attached to the at least one elongated electrode shank and are in electrical communication with the at least one electrode contact. In an embodiment, a plurality of the at least one elongated electrode shanks are arranged into a matrix.

Graphene Electrodes On A Planar Cubic Silicon Carbide (3C-Sic) Long Term Implantable Neuronal Prosthetic Device

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US Patent:
20130338744, Dec 19, 2013
Filed:
May 30, 2013
Appl. No.:
13/905909
Inventors:
Christopher Leroy Frewin - Tampa FL, US
Stephen E. Saddow - Odessa FL, US
Camilla Coletti - Pisa, IT
Assignee:
Max-Planck-Institute for Solid State Research - Stuttgart
University of South Florida - Tampa FL
International Classification:
A61N 1/05
US Classification:
607116, 29846
Abstract:
Graphene, can be used to make an implantable neuronal prosthetic which can be indefinitely implanted in vivo. Graphene electrodes are placed on a 3C—SiC shank and electrical insulation is provided by conformal insulating SiC. These materials are not only chemically resilient, physically durable, and have excellent electrical properties, but have demonstrated a very high degree of biocompatibility. Graphene also has a large specific capacitance in electrolytic solutions as well as a large surface area which reduces the chances for irreversible Faradaic reactions. Graphene can easily be constructed on SiC by the evaporation of Si from the surface of that material allowing for mechanically robust epitaxial graphene layers that can be fashioned into electrodes using standard lithography and etching methods.

Optical Neuron Stimulation Prosthetic Using Silicon Carbide

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US Patent:
20140067023, Mar 6, 2014
Filed:
Jul 29, 2013
Appl. No.:
13/953224
Inventors:
Joseph J. Register - Tampa FL, US
Stephen E. Saddow - Odessa FL, US
Christopher L. Frewin - Tampa FL, US
Edwin Weeber - Apollo Beach FL, US
Assignee:
UNIVERSITY OF SOUTH FLORIDA - Tampa FL
International Classification:
A61N 5/06
US Classification:
607 89, 607 92, 29428
Abstract:
The microfabricated prosthetic device uses local, direct, and wavelength-specific optical stimulation to achieve an action potential from a single or small group of neurons within the central nervous system (CNS). The device is biocompatible, mechanically flexible, and optically transparent. The device can also use integrated electrodes for additional input/output (IO) locations, signal verification, feedback, wireless communication, and characterization of the electrochemically-evoked potential received from the activated neuron. The purpose of the device is to act as a neural interface prosthetic. The prosthetic is designed as the central component of a brain machine interface (BMI).

Methods For Treating Cancer Using X-Ray-Induced Near Infrared Photoimmunotherapy

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US Patent:
20220241418, Aug 4, 2022
Filed:
Jun 10, 2020
Appl. No.:
17/617652
Inventors:
Stephen Edward SADDOW - Land O Lakes FL, US
Peter L. CHOYKE - Rockville MD, US
- Tampa FL, US
International Classification:
A61K 41/00
A61N 5/06
A61N 5/10
A61K 47/68
A61K 47/69
Abstract:
Methods for the treatment of cancers, in particular deep-tissue cancers, using x-ray induced near-infrared photoimmunotherapy are described herein.

Determining Electronic Component Authenticity Via Electronic Signal Signature Measurement

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US Patent:
20230038377, Feb 9, 2023
Filed:
Apr 2, 2021
Appl. No.:
17/608838
Inventors:
- Tampa FL, US
Feng YU - Lutz FL, US
Stephen Edward SADDOW - Land O Lakes FL, US
Assignee:
University of South Florida - Tampa FL
International Classification:
G06F 21/44
G01R 31/52
G01R 27/16
G01R 31/28
Abstract:
Examples of determining electronic component authenticity via electronic signal signature measurement are discussed. Reference pin identifiers corresponding to pins of a known authentic electronic component are determined. Measurement values corresponding to characteristics of pins of an electronic component are obtained, and pin identifiers based on the measurement values are generated. Accordingly, an indication that the electronic component is authentic can be provided based at least in part on a comparison of the pin identifiers and the reference pin identifiers.

Systems And Methods For Detecting Alcohol, Acetone, And Carbon Monoxide In Breath

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US Patent:
20210321904, Oct 21, 2021
Filed:
Apr 20, 2021
Appl. No.:
17/235259
Inventors:
- Tampa FL, US
Salvatore Domenic Morgera - Tampa FL, US
Stephen Edward Saddow - Tampa FL, US
Arash Takshi - Tampa FL, US
International Classification:
A61B 5/08
A61B 5/097
A61B 5/00
Abstract:
A breath collection device can detect changes associated with pathogenesis of a disease, such as COVID-19, including biomarkers of immune response for respiratory symptoms, central nervous system injury, and/or peripheral nervous system injury in user breath and/or odor. The breath collection device can detect concentrations of alcohol, acetone, and carbon monoxide in user breath samples. A breath sample can be received in an internal bladder of the device for sensor analysis. Concentrations of alcohol, acetone, and carbon monoxide can be determined by calibrated calculation. A detection method for alcohol, acetone, and carbon monoxide can provide a non-invasive, rapid, and selective detection of gases in a variety of applications in virus detection as well as agricultural and homeland security.

System And Method For Non-Invasive Blood Glucose Monitoring

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US Patent:
20190231237, Aug 1, 2019
Filed:
Jan 30, 2019
Appl. No.:
16/262836
Inventors:
Stephen E. Saddow - Land O' Lakes FL, US
Fabiola Araujo Cespedes - Temple Terrace FL, US
Gokhan Mumcu - Tampa FL, US
Christopher Leroy Frewin - Ann Arbor MI, US
Assignee:
University of South Florida - Tampa FL
International Classification:
A61B 5/145
A61B 5/05
A61B 5/00
H01Q 1/27
H01Q 9/04
Abstract:
A system and method for continuous glucose monitoring (CGM) of blood in a blood vessel of a patient using a non-invasive sensor composed of a patch antenna operating in the Industrial, Scientific and Medical (ISM) Radio band (5.725 GHz-5.875 GHz). The device determines the blood glucose concentration of the blood in the blood vessel based on the measured shift of the resonant frequency of the non-invasive antenna patch sensor. A radio frequency (RF) synthesizer is used to drive the patch antenna with a fraction of its output coupled to both the antenna and receiver through a directional coupler. In this approach both the transmitted (FWD) and received (REV) power are processed, by demodulating logarithmic amplifiers, which convert the RF signals to corresponding voltages for downstream processing. The resulting voltages are then fed into a microcontroller and the measured shift in resonant frequency is converted to a real-time glucose concentration.

Isbn (Books And Publications)

Silicon Carbide and Related Materials

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Author

Stephen E. Saddow

ISBN #

0878494251

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Stephen E Saddow from Tampa, FL, age ~63 Get Report