John Paul Butters, 443924 Saint Francis St SW, Lakewood, WA 98499

6724188, Apr 20, 2004

Mar 29, 2002

10/112927

John T. Butters - Langley WA
Bennett M. Butters - Lacey WA
Lisa C. Butters - Langley WA

Wavbank, Inc. - Seattle WA

G01R 3302

324248, 324239, 324261

An apparatus and method for the repeatable detection and recording of low-threshold molecular electromagnetic signals. The sample material and detection apparatus are contained with a magnetically shielded faraday cage to shield them from extraneous electromagnetic signals. The detection apparatus includes a detection coil and Super Conducting Quantum Interference Device (âSQUIDâ). White noise is injected external to the SQUID and the signals emitted by the sample material enhanced by stochastic resonance.

7081747, Jul 25, 2006

Aug 20, 2004

10/923545

John T. Butters - Langley WA, US
Bennett M. Butters - Lacey WA, US
Lisa C. Butters - Langley WA, US

Nativis, Inc. - La Jolla CA

G01R 33/02

324248, 324244, 702 75

A method and apparatus for interrogating a sample that exhibits molecular rotation are disclosed. In practicing the method, the sample is placed in a container having both magnetic and electromagnetic shielding, and Gaussian noise is injected into the sample. An electromagnetic time-domain signal composed of sample source radiation superimposed on the injected Guassian noise is detected, and this signal is cross-correlated with a second time-domain signal produced by the same or similar sample, to produce a cross-correlated signal with frequency domain components. The latter is plotted in the frequency domain by a fast Fourier transform to produce a frequency domain spectrum in a frequency range within DC to 50 KHz. From this spectrum, one or more low-frequency signal components that are characteristic of the sample being interrogated are identified.

2011019, Aug 11, 2011

Dec 17, 2010

12/972089

B. Michael Butters - Lacey WA, US
John T. Butters - Del Mar CA, US
Christine Bonzon - San Diego CA, US
Marco Gymnopoulos - San Diego CA, US
Mayra Montes Camacho - National City CA, US

NATIVIS, INC. - La Jolla CA

A61K 31/337
A61K 9/127
A61P 35/00
A61K 31/7105
C12N 5/09
G01J 3/44
G01J 3/00
G01R 33/12
B82Y 5/00

424450, 514449, 514 44 A, 435375, 356301, 356 51, 324228, 977773

A method of forming an aqueous composition effective to produce an agent-specific effect on an agent-responsive chemical or biological system, when the composition is added to the system, is disclosed. The composition is formed by exposing an aqueous medium to a low-frequency, time-domain signal derived from the agent, until the aqueous medium acquires a detectable agent activity. Exemplary compositions are formed by exposure to a paclitaxel signal or a signal derived from a therapeutic oligonucleotide, such as GAPDH antisense RNA and PCSK9 antisense RNA. Also disclosed are methods for confirming the activity of the composition, and for preparing and testing the activity of the compositions.

2013016, Jun 27, 2013

Oct 26, 2012

13/662164

John T. Butters - Langley WA, US

Nativis, Inc. - Seattle WA

A61N 2/00
G01N 27/00

600 13, 324228

A storage medium having a low frequency time-domain signal stored thereon, and methods of generating, scoring, testing and using the signals are disclosed. In one general embodiment, the signal is derived from a taxane-like compound or an siRNA against human GADPH, and is useful in treating cancer in a subject by exposing the subject a low-magnetic field transduction of the signal. Also disclosed are improved signal transduction methods.

2022029, Sep 22, 2022

Mar 15, 2022

17/695482

- Seattle WA, US
John T. Butters - Seattle WA, US

A61N 2/02
A61K 41/00
G01N 27/74

A measurement system includes a container configured to contain a solvated target molecule and at least one magnetoresistive (MR) sensor device including at least one MR sensor disposed near the container and configured to measure a magnetic field generated by the solvated target molecule, each of the at least one MR sensor including a pin layer having a pinned direction of magnetization, a free layer having a direction of magnetization that varies with an applied magnetic field, and a non-conductive layer separating the pin layer and the free layer.

2022021, Jul 7, 2022

Mar 21, 2022

17/655654

- Seattle WA, US
John Butters - Seattle WA, US

G01R 33/26
G01R 33/032

Time-multiplexed atomic magnetometry uses first and second atomic vapor cells to measure an external magnetic field. Each vapor cell operates according to a sequence of alternating pumping and probing stages. However, the sequences are temporally offset from each other such that the second vapor cell is pumped while the first vapor cell is probed, and the first vapor cell is pumped while the second vapor cell is probed. With this time-multiplexed operation, the external magnetic field can be measured without any time gaps. The Hilbert transform of the signals may be taken to obtain their instantaneous phases, which may then be interleaved to form a single gapless time sequence that represents the external magnetic field over a time window that lasts for several continuous pumping/probing stages.

2021036, Nov 25, 2021

May 13, 2021

17/320144

- Seattle WA, US
John T. Butters - Seattle WA, US

A61N 2/02
G16H 40/67
G16H 20/30

A therapy delivery system includes a near field magnetic induction (NFMI) transceiver device configured to be worn or otherwise disposed on a patient, the NFMI transceiver device including a NFMI transceiver; and a therapy delivery device including a NFMI receiver configured to receive signals from the NFMI transceiver device and a therapy delivery circuit configured to deliver a therapeutic magnetic signal, based, at least in part, on the received signals from the NFMI transceiver device, to the patient when the patient wears the therapy delivery device or has the therapy delivery device disposed on skin of the patient or has the therapy delivery device implanted.

2017006, Mar 9, 2017

Jul 11, 2013

15/128938

- Seattle WA, US
John T. BUTTERS - Langley WA, US

G01R 33/032
G01N 27/72

A system for analyzing signals produced from a sample is described, where the system includes at least one magnetometer, where the magnetometer is capable of detecting magnetic fields produced by a sample. The magnetometer is positioned proximate to the sample, and is miniaturized (e.g. has a size less than 6 cm per side). A noise producing component is configured to uniformly produce noise surrounding the sample and the magnetometer, where the noise produced is capable of inducing stochastic resonance in the sample to amplify characteristic signals of the sample. At least one shielding structure electromagnetically shields the sample and the first magnetometer from external electromagnetic radiation