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Scott Manalis Phones & Addresses

  • 8 Magazine Ct, Cambridge, MA 02139 (617) 441-9910
  • 100 Memorial Dr, Cambridge, MA 02142 (617) 441-9910
  • Stanford, CA
  • Coshocton, OH
  • 390 Merida Dr, Santa Barbara, CA 93111 (805) 683-8519
  • 100 Memorial Dr APT 2-9C, Cambridge, MA 02142 (617) 593-7764

Work

Company: Massachusetts institute of technology (mit) Position: Professor

Education

Degree: Associate degree or higher

Industries

Higher Education

Resumes

Resumes

Scott Manalis Photo 1

Professor

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Location:
Cambridge, MA
Industry:
Higher Education
Work:
Massachusetts Institute of Technology (Mit)
Professor

Business Records

Name / Title
Company / Classification
Phones & Addresses
Scott Manalis
CEO, executive officer, Administrator
Scott Manalis
100 Memorial Dr APT 2-9C - CAMBRIDGE, Cambridge, MA 02238
(617) 441-9910
Scott Manalis
Affinity Biosensors, LLC
Product Development of Instruments for A · Manufacture Particle Size Analyzers · Mfg Analytical Instruments
75 Robin Hl Rd, Santa Barbara, CA 93117
75D Robin Hl Rd, Goleta, CA 93117
(805) 455-0181

Publications

Us Patents

Methods For Manufacturing Electronic And Electromechanical Elements And Devices By Thin-Film Deposition And Imaging

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US Patent:
6348295, Feb 19, 2002
Filed:
Mar 3, 2000
Appl. No.:
09/519722
Inventors:
Saul Griffith - Cambridge MA
Joseph M. Jacobson - Newton MA
Scott Manalis - Cambridge MA
Assignee:
Massachusetts Institute of Technology - Cambridge MA
International Classification:
G03F 700
US Classification:
430198, 430311, 430315, 430 31, 430545, 427 96, 427554, 427559
Abstract:
Electrically (and, possibly, mechanically) active patterns are applied using a colloidal suspension of nanoparticles that exhibit a desired electrical characteristic. The nanoparticles are surrounded by an insulative shells that may be removed by therefrom by application of energy (e. g. , in the form of electromagnetic radiation or heat). The nanoparticle suspension is applied to a surface, forming a layer that is substantially insulative owing to the nanoparticle shells. The applied suspension is exposed to energy to remove the capping groups and fuse the particles into cohesion. If the nanoparticle suspension was deposited as a uniform film, the energy is applied in a desired pattern so that unexposed areas remain insulative while exposed areas exhibit the electrical behavior associated with the nanoparticles. If the nanoparticle suspension was deposited in a desired pattern, it may be uniformly exposed to energy. Additional layers may be applied in the same manner, one over the other, to form a multilayer device.

High-Sensitivity Interferometric Accelerometer

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US Patent:
6473187, Oct 29, 2002
Filed:
Aug 11, 2000
Appl. No.:
09/638210
Inventors:
Scott Manalis - Cambridge MA
Assignee:
Massachusetts Institute of Technology - Cambridge MA
International Classification:
G01B 9026
US Classification:
356521, 7351426
Abstract:
An accelerometer facilitates optical, interferometric measurement of acceleration. The device includes a proof mass having a first set of spaced-apart, elongated fingers projecting therefrom, and a stationary housing or substrate comprising a second set of similarly arranged projecting fingers. A spring connects the proof mass to the substrate such that, in a rest configuration, the first and second set of fingers interdigitate. When the structure is accelerated, the substrate fingers remain stationary, while the alternating fingers of the proof mass are displaced therefrom. This creates a phase-sensitive diffraction grating which, when illuminated, facilitates determination of the relative displacement between the sets of fingers by measuring the intensity of the diffracted modes. This displacement, in turn, indicates the acceleration experienced by the accelerometer structure.

High-Density Data Storage Using Atomic Force Microscope

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US Patent:
6519221, Feb 11, 2003
Filed:
Oct 6, 2000
Appl. No.:
09/680290
Inventors:
Scott Manalis - Santa Barbara CA
Emily B. Cooper - Cambridge MA
Calvin F. Quate - Stanford CA
Assignee:
Massachusetts Institute of Technology - Cambridge MA
The Board of Trustees of Leland Stanford Junior University - Palo Alto CA
International Classification:
G11B 700
US Classification:
369126, 250306
Abstract:
An atomic force microscope (AFM) tipped with a single-wall conductive nanotube is operated to write bits onto a metal substrate by oxidizing the surface. The oxidized microregions project above an otherwise flat surface, and can therefore be detectedâthat is, the written bits can be readâusing the same AFM arrangement.

Methods And Apparatus For Manufacturing Electronic And Electromechanical Elements And Devices By Thin-Film Deposition And Imaging

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US Patent:
6664027, Dec 16, 2003
Filed:
Jan 30, 2002
Appl. No.:
10/060151
Inventors:
Saul Griffith - Cambridge MA
Joseph M. Jacobson - Newton MA
Scott Manalis - Cambridge MA
Assignee:
Massachusetts Institute of Technology - Cambridge MA
International Classification:
G03F 700
US Classification:
430311, 430325
Abstract:
Electrically (and, possibly, mechanically) active patterns are applied using a colloidal suspension of nanoparticles that exhibit a desired electrical characteristic. The nanoparticles are surrounded by an insulative shells that may be removed by therefrom by application of energy (e. g. , in the form of electromagnetic radiation or heat). The nanoparticle suspension is applied to a surface, forming a layer that is substantially insulative owing to the nanoparticle shells. The applied suspension is exposed to energy to remove the capping groups and fuse the particles into cohesion. If the nanoparticle suspension was deposited as a uniform film, the energy is applied in a desired pattern so that unexposed areas remain insulative while exposed areas exhibit the electrical behavior associated with the nanoparticles. If the nanoparticle suspension was deposited in a desired pattern, it may be uniformly exposed to energy. Additional layers may be applied in the same manner, one over the other, to form a multilayer device.

Direct Dna Sequencing With A Transcription Protein And A Nanometer Scale Electrometer

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US Patent:
6770472, Aug 3, 2004
Filed:
Nov 13, 2001
Appl. No.:
09/993338
Inventors:
Scott R. Manalis - Santa Barbara CA
Stephen C. Minne - Danville IL
Calvin F. Quate - Menlo Park CA
Assignee:
The Board of Trustees of the Leland Stanford Junior University - Palo Alto CA
International Classification:
C12M 134
US Classification:
4352872, 4352883, 20440303, 20440313
Abstract:
The present invention provides an apparatus and method for nucleotide or DNA sequencing by monitoring the molecular charge configuration as the DNA moves through a protein that is capable of transcribing the DNA. The apparatus and method provides a nanoscale electrometer that immobilizes the protein. The protein receives the DNA and transcribes the DNA. The nanoscale electrometer is a sensitive device that is capable of sensing and measuring the electronic charge that is released during the transcription process. The apparatus and method of the present invention further provides monitoring means that are attached to the nanoscale electrometer to monitor the electronic charge configuration as the DNA moves through the protein. Once the electronic charge configuration is established, a correlation is computed, using computing means, between the electronic charge configuration and a nucleotide signature of the DNA.

Methods For Manufacturing Bioelectronic Devices

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US Patent:
6815218, Nov 9, 2004
Filed:
Jun 8, 2000
Appl. No.:
09/590044
Inventors:
Joseph M. Jacobson - Newton MA
Scott Manalis - Cambridge MA
Brent Ridley - Cambridge MA
Assignee:
Massachusetts Institute of Technology - Cambridge MA
International Classification:
H01L 2100
US Classification:
438 1, 438 49, 438800
Abstract:
Bioelectronic components are formed using nanoparticles surrounded by attached shells of at least one biological material. The nanoparticles are deposited (e. g. , using a printing process) onto a surface, and by associating the deposited nanoparticles with one or more electrical contacts, electrical measurement across the nanoparticles (and, consequently, across the biological material) may be made. A finished component may include multiple layers formed by nanoparticle deposition.

Suspended Microchannel Detectors

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US Patent:
7282329, Oct 16, 2007
Filed:
Sep 23, 2003
Appl. No.:
10/669883
Inventors:
Scott Manalis - Cambridge MA, US
Thomas Burg - Cambridge MA, US
Assignee:
Massachusetts Institute of Technology - Cambridge MA
International Classification:
C12Q 1/68
C12M 1/36
G01N 15/06
C07H 21/04
US Classification:
435 6, 4352831, 4352872, 4352873, 4352885, 422 681, 536 231
Abstract:
An apparatus for detecting an analyte in solution that has a suspended beam containing at least one microfluidic channel containing a capture ligand that bonds to or reacts with an analyte. The apparatus also includes at least one detector for measuring a change in the beam upon binding or reaction of the analyte. A method of making the suspended microfluidic channels is disclosed, as well as, a method of integrating the microfluidic device with conventional microfluidics having larger sample fluid channels.

Measurement Of Concentrations And Binding Energetics

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US Patent:
7387889, Jun 17, 2008
Filed:
Jan 2, 2003
Appl. No.:
10/336549
Inventors:
Scott Manalis - Cambridge MA, US
Assignee:
Massachusetts Institute of Technology - Cambridge MA
International Classification:
C12M 1/34
C12M 1/00
G01N 25/00
G01N 21/00
G01N 33/53
US Classification:
4352871, 436147, 436501, 436164, 435 71, 4352831, 422 51, 422 681
Abstract:
Free-standing microfluidic channels are used to both transport and analyze molecules of interest. In a biochemical context, such molecules may be polypeptides, nucleic acids, or other biomolecules. The free-standing channels provide a real-time readout of concentration without the need for labeling with reporter molecules. The channels can also measure enthalpy values and equilibrium constants by detecting heat released from or absorbed by the sample.

Amazon

Bringing Scanning Probe Microscopy up to Speed (Microsystems)

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Bringing Scanning Probe Microscopy Up to Speed introduces the principles of scanning probe systems with particular emphasis on techniques for increasing speed. The authors include useful information on the characteristics and limitations of current state-of-the-art machines as well as the properties...

Author

Stephen C. Minne, Scott R. Manalis, Calvin F. Quate

Binding

Hardcover

Pages

159

Publisher

Springer

ISBN #

0792384660

EAN Code

9780792384663

ISBN #

2

Bringing Scanning Probe Microscopy up to Speed (Microsystems)

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Bringing Scanning Probe Microscopy Up to Speed introduces the principles of scanning probe systems with particular emphasis on techniques for increasing speed. The authors include useful information on the characteristics and limitations of current state-of-the-art machines as well as the properties...

Author

Stephen C. Minne, Scott R. Manalis, Calvin F. Quate

Binding

Paperback

Pages

159

Publisher

Springer

ISBN #

1461373530

EAN Code

9781461373537

ISBN #

1

Scott R Manalis from Cambridge, MA, age ~52 Get Report