Patents by Inventor Torsten Hegmann

Torsten Hegmann has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).

  • Publication number: 20210325358
    Abstract: A sensor for detecting non-hazardous and especially hazardous gases and/or vapors comprises a liquid crystal cell generally having a standard substrate and a conductive electrode layer thereon. An alignment layer is desirably located on the electrode layer and contains one or more types of metal nanoparticles that cover at least a portion of the alignment layer. The nanoparticles contain at least one type of ligand thereon that is capable of sensing a specific type of non-hazardous or hazardous gas. The sensor is very sensitive and can detect the gases or vapors contained within air, or the like, up to 1 part per million.
    Type: Application
    Filed: June 22, 2021
    Publication date: October 21, 2021
    Applicant: Kent State University
    Inventors: Torsten HEGMANN, Elda HEGMANN, Marianne PRÉVÔT, Ahlam NEMATI, Julie VANEGAS GARCIA
  • Publication number: 20210140932
    Abstract: A sensor for detecting non-hazardous and especially hazardous gases and/or vapors comprises a liquid crystal cell generally having a standard substrate and a conductive electrode layer thereon. An alignment layer is desirably located on the electrode layer and contains one or more types of metal nanoparticles that cover at least a portion of the alignment layer. The nanoparticles contain at least one type of ligand thereon that is capable of sensing a specific type of non-hazardous or hazardous gas. The sensor is very sensitive and can detect the gases or vapors contained within air, or the like, up to 1 part per million.
    Type: Application
    Filed: December 16, 2020
    Publication date: May 13, 2021
    Inventors: Torsten HEGMANN, Elda HEGMANN, Marianne PRÉVÔT, Ahlam NEMATI, Julie VANEGAS GARCIA
  • Publication number: 20200355664
    Abstract: A sensor for detecting non-hazardous and especially hazardous gases and/or vapors comprises a liquid crystal cell generally having a standard substrate and a conductive electrode layer thereon. An alignment layer is desirably located on the electrode layer and contains one or more types of metal nanoparticles that cover at least a portion of the alignment layer. The nanoparticles contain at least one type of ligand thereon that is capable of sensing a specific type of non-hazardous or hazardous gas. The sensor is very sensitive and can detect the gases or vapors contained within air, or the like, up to 1 part per million.
    Type: Application
    Filed: November 13, 2018
    Publication date: November 12, 2020
    Inventors: Torsten HEGMANN, Elda HEGMANN, Marianne PRÉVÔT, Ahlam NEMATI, Julie VANEGAS GARCIA
  • Patent number: 10788713
    Abstract: Ink-jet printable compositions including nanoparticles capped with a protective layer of hydrocarbon chains and a single solvent exhibiting a single evaporation rate and having a specifically defined viscosity and surface tension that result in uniform and printable alignment layers for liquid crystal materials. Patterned liquid crystal-containing cells are also disclosed including one or more layers including the same or different nanoparticles capped with a protective layer of hydrocarbon chains printed on a surface of a substrate or even another nanoparticle-containing layer. Methods for producing the cells are also disclosed, including the step of printing a pattern on one or more portions of a cell surface utilizing a composition comprising the capped nanoparticles. Devices including the cells are also disclosed.
    Type: Grant
    Filed: November 13, 2018
    Date of Patent: September 29, 2020
    Assignee: KENT STATE UNIVERSITY
    Inventors: Torsten Hegmann, Anshul Sharma, Dmytro Reznikov
  • Patent number: 10709815
    Abstract: Star block copolymers having 3 to 8 arms are formed as a 3D foam scaffold having tailor-made pore sizes that mimic an actual cell size of a specific animal and/or human tissue and/or organs. The pore sizes are made within the elastomeric foams via a salt leaching process wherein a salt of a specific particle size is blended within the star block copolymers and crosslinked as by polyisocyanate compounds. Water or other suitable solvent are utilized to dissolve and leach out the salt leaving an open pore system. Animal and/or human cells are then injected into the 3D elastomeric foam scaffold that contains pendant liquid crystals on the star block copolymer whereby with the aid of nutrients, cells are formed within the pore system that are viable for at least three months. The size of the pore is predetermined to produce a desired cultured cell having a desired size.
    Type: Grant
    Filed: November 1, 2017
    Date of Patent: July 14, 2020
    Assignee: Kent State University
    Inventors: Elda Hegmann, Marianne E. Prévôt, Torsten Hegmann
  • Patent number: 10568986
    Abstract: A polymeric scaffold contains pendant liquid crystal side chains and has fully interconnected pores. Such a polymeric scaffold will preferably be 3D in nature and elastomeric, biocompatible and biodegradable. Such 3D liquid crystal elastomer (LCE) scaffolds can be used for various biomedical applications, including cell culture applications. A method for the production of such a polymeric scaffold containing liquid crystals and having interconnected pores is also disclosed that uses a metal foam sacrificial template as a scaffold to produce the polymeric smart response scaffold of the present invention. Consistent and controlled pore sizes result from etching the sacrificial metal foam template away from the polymeric scaffold, permitting the incorporation of growth factors, when needed, for enhancing cell viability and proliferation.
    Type: Grant
    Filed: December 19, 2014
    Date of Patent: February 25, 2020
    Assignee: KENT STATE UNIVERSITY
    Inventors: Elda Hegmann, Torsten Hegmann, Yunxiang Gao
  • Patent number: 10563012
    Abstract: Controlled biodegradable smart responsive scaffold (SRS) materials enhance attachment and viability of cells, i.e. actively guiding their expansion, proliferation and in some cases differentiation, while increasing their biomechanical functionality is an important key issue for tissue regeneration. Chemically build-in functionality in these biodegradable SRS materials is achieved by varying structural functionalization with biocompatible liquid crystal motifs and general polymer composition allowing for regulation and alteration of tensile strength, surface ordering, bioadhesion and biodegradability, bulk liquid crystal phase behavior, porosity, and cell response to external stimuli. Liquid crystal modification of such polymeric scaffolds is an ideal tool to induce macroscopic ordering events through external stimuli.
    Type: Grant
    Filed: November 7, 2017
    Date of Patent: February 18, 2020
    Assignee: KENT STATE UNIVERSITY
    Inventors: Elda Hegmann, Torsten Hegmann, Anshul Sharma, Abdollah Neshat
  • Patent number: 10545383
    Abstract: Ink-jet printable compositions including nanoparticles capped with a protective layer of hydrocarbon chains and a single solvent exhibiting a single evaporation rate and having a specifically defined viscosity and surface tension that result in uniform and printable alignment layers for liquid crystal materials. Patterned liquid crystal-containing cells are also disclosed including one or more layers including the same or different nanoparticles capped with a protective layer of hydrocarbon chains printed on a surface of a substrate or even another nanoparticle-containing layer. Methods for producing the cells are also disclosed, including the step of printing a pattern on one or more portions of a cell surface utilizing a composition comprising the capped nanoparticles. Devices including the cells are also disclosed.
    Type: Grant
    Filed: November 13, 2018
    Date of Patent: January 28, 2020
    Assignee: KENT STATE UNIVERSITY
    Inventors: Torsten Hegmann, Anshul Sharma, Dmytro Reznikov
  • Publication number: 20190111185
    Abstract: Star block copolymers having 3 to 8 arms are formed as a 3D foam scaffold having tailor-made pore sizes that mimic an actual cell size of a specific animal and/or human tissue and/or organs. The pore sizes are made within the elastomeric foams via a salt leaching process wherein a salt of a specific particle size is blended within the star block copolymers and crosslinked as by polyisocyanate compounds. Water or other suitable solvent are utilized to dissolve and leach out the salt leaving an open pore system. Animal and/or human cells are then injected into the 3D elastomeric foam scaffold that contains pendant liquid crystals on the star block copolymer whereby with the aid of nutrients, cells are formed within the pore system that are viable for at least three months. The size of the pore is predetermined to produce a desired cultured cell having a desired size.
    Type: Application
    Filed: November 1, 2017
    Publication date: April 18, 2019
    Inventors: Elda HEGMANN, Marianne E. PRÉVÔT, Torsten HEGMANN
  • Publication number: 20190085244
    Abstract: Ink-jet printable compositions including nanoparticles capped with a protective layer of hydrocarbon chains and a single solvent exhibiting a single evaporation rate and having a specifically defined viscosity and surface tension that result in uniform and printable alignment layers for liquid crystal materials. Patterned liquid crystal-containing cells are also disclosed including one or more layers including the same or different nanoparticles capped with a protective layer of hydrocarbon chains printed on a surface of a substrate or even another nanoparticle-containing layer. Methods for producing the cells are also disclosed, including the step of printing a pattern on one or more portions of a cell surface utilizing a composition comprising the capped nanoparticles. Devices including the cells are also disclosed.
    Type: Application
    Filed: November 13, 2018
    Publication date: March 21, 2019
    Inventors: Torsten HEGMANN, Anshul SHARMA, Dmytro REZNIKOV
  • Publication number: 20190085245
    Abstract: Ink-jet printable compositions including nanoparticles capped with a protective layer of hydrocarbon chains and a single solvent exhibiting a single evaporation rate and having a specifically defined viscosity and surface tension that result in uniform and printable alignment layers for liquid crystal materials. Patterned liquid crystal-containing cells are also disclosed including one or more layers including the same or different nanoparticles capped with a protective layer of hydrocarbon chains printed on a surface of a substrate or even another nanoparticle-containing layer. Methods for producing the cells are also disclosed, including the step of printing a pattern on one or more portions of a cell surface utilizing a composition comprising the capped nanoparticles. Devices including the cells are also disclosed.
    Type: Application
    Filed: November 13, 2018
    Publication date: March 21, 2019
    Inventors: Torsten HEGMANN, Anshul SHARMA, Dmytro REZNIKOV
  • Patent number: 10150918
    Abstract: Ink-jet printable compositions including nanoparticles capped with a protective layer of hydrocarbon chains and a single solvent exhibiting a single evaporation rate and having a specifically defined viscosity and surface tension that result in uniform and printable alignment layers for liquid crystal materials. Patterned liquid crystal-containing cells are also disclosed including one or more layers including the same or different nanoparticles capped with a protective layer of hydrocarbon chains printed on a surface of a substrate or even another nanoparticle-containing layer. Methods for producing the cells are also disclosed, including the step of printing a pattern on one or more portions of a cell surface utilizing a composition comprising the capped nanoparticles. Devices including the cells are also disclosed.
    Type: Grant
    Filed: April 14, 2014
    Date of Patent: December 11, 2018
    Assignee: Kent State University
    Inventors: Torsten Hegmann, Anshul Sharma, Dmytro Reznikov
  • Publication number: 20180297857
    Abstract: A low temperature, aqueous synthesis of polyhedral iron oxide nanoparticles (IONPs) is presented. The modification of the co-precipitation hydrolysis method with Triton X surfactants results in the formation of crystalline polyhedral particles. The particles are herein termed iron oxide “nanobricks” (IONBs), as the varieties of particles made are all variations on a simple “brick-like”, polyhedral shape such as rhombohedral shape or parallelogram as evaluated by TEM. These IONBs can be easily coated with hydrophilic silane ligands, allowing them to be dispersed in aqueous media. The dispersed particles are investigated for potential applications as hyperthermia and T2 MRI contrast agents. The results demonstrate that the IONBs perform better than comparable spherical IONPs in both applications, and show r2 values amongst the highest for iron oxide based materials reported in the literature.
    Type: Application
    Filed: May 25, 2016
    Publication date: October 18, 2018
    Inventors: Torsten HEGMANN, Matthew WORDEN, Donald W. Miller
  • Publication number: 20180105642
    Abstract: Controlled biodegradable smart responsive scaffold (SRS) materials enhance attachment and viability of cells, i.e. actively guiding their expansion, proliferation and in some cases differentiation, while increasing their biomechanical functionality is an important key issue for tissue regeneration. Chemically build-in functionality in these biodegradable SRS materials is achieved by varying structural functionalization with biocompatible liquid crystal motifs and general polymer composition allowing for regulation and alteration of tensile strength, surface ordering, bioadhesion and biodegradability, bulk liquid crystal phase behavior, porosity, and cell response to external stimuli. Liquid crystal modification of such polymeric scaffolds is an ideal tool to induce macroscopic ordering events through external stimuli.
    Type: Application
    Filed: November 7, 2017
    Publication date: April 19, 2018
    Inventors: Elda HEGMANN, Torsten HEGMANN, Anshul SHARMA, Abdollah NESHAT
  • Patent number: 9815935
    Abstract: Controlled biodegradable smart responsive scaffold (SRS) materials enhance attachment and viability of cells, i.e. actively guiding their expansion, proliferation and in some cases differentiation, while increasing their biomechanical functionality is an important key issue for tissue regeneration. Chemically build-in functionality in these biodegradable SRS materials is achieved by varying structural functionalization with biocompatible liquid crystal motifs and general polymer composition allowing for regulation and alteration of tensile strength, surface ordering, bioadhesion and biodegradability, bulk liquid crystal phase behavior, porosity, and cell response to external stimuli. Liquid crystal modification of such polymeric scaffolds is an ideal tool to induce macroscopic ordering events through external stimuli.
    Type: Grant
    Filed: April 14, 2014
    Date of Patent: November 14, 2017
    Assignee: KENT STATE UNIVERSITY
    Inventors: Elda Hegmann, Torsten Hegmann, Anshul Sharma, Abdollah Neshat
  • Publication number: 20160339145
    Abstract: A polymeric scaffold contains pendant liquid crystal side chains and has fully interconnected pores. Such a polymeric scaffold will preferably be 3D in nature and elastomeric, biocompatible and biodegradable. Such 3D liquid crystal elastomer (LCE) scaffolds can be used for various biomedical applications, including cell culture applications. A method for the production of such a polymeric scaffold containing liquid crystals and having interconnected pores is also disclosed that uses a metal foam sacrificial template as a scaffold to produce the polymeric smart response scaffold of the present invention. Consistent and controlled pore sizes result from etching the sacrificial metal foam template away from the polymeric scaffold, permitting the incorporation of growth factors, when needed, for enhancing cell viability and proliferation.
    Type: Application
    Filed: December 19, 2014
    Publication date: November 24, 2016
    Inventors: Elda Hegmann, Torsten Hegmann, Yunxiang Gao
  • Publication number: 20160060529
    Abstract: Ink-jet printable compositions including nanoparticles capped with a protective layer of hydrocarbon chains and a single solvent exhibiting a single evaporation rate and having a specifically defined viscosity and surface tension that result in uniform and printable alignment layers for liquid crystal materials. Patterned liquid crystal-containing cells are also disclosed including one or more layers including the same or different nanoparticles capped with a protective layer of hydrocarbon chains printed on a surface of a substrate or even another nano-particle-containing layer. Methods for producing the cells are also disclosed, including the step of printing a pattern on one or more portions of a cell surface utilizing a composition comprising the capped nanoparticles. Devices including the cells are also disclosed.
    Type: Application
    Filed: April 14, 2014
    Publication date: March 3, 2016
    Inventors: Torsten HEGMANN, Anshul SHARMA, Dmytro REZNIKOV
  • Publication number: 20160046761
    Abstract: Controlled biodegradable smart responsive scaffold (SRS) materials enhance attachment and viability of cells, i.e. actively guiding their expansion, proliferation and in some cases differentiation, while increasing their biomechanical functionality is an important key issue for tissue regeneration. Chemically build-in functionality in these biodegradable SRS materials is achieved by varying structural functionalization with biocompatible liquid crystal motifs and general polymer composition allowing for regulation and alteration of tensile strength, surface ordering, bioadhesion and biodegradability, bulk liquid crystal phase behavior, porosity, and cell response to external stimuli. Liquid crystal modification of such polymeric scaffolds is an ideal tool to induce macroscopic ordering events through external stimuli.
    Type: Application
    Filed: April 14, 2014
    Publication date: February 18, 2016
    Inventors: Elda HEGMANN, Torsten HEGMANN, Anshul SHARMA, Abdollah NESHAT
  • Patent number: 8383085
    Abstract: A method of making iron-containing nanoparticles (e.g., magnetite nanoparticles) that includes contacting an iron-containing precursor with a reducing agent at a temperature less than 200° C. and allowing the mixture to react to form magnetite nanoparticles.
    Type: Grant
    Filed: February 22, 2010
    Date of Patent: February 26, 2013
    Assignee: University of Manitoba
    Inventors: Torsten Hegmann, Vinith Yathindranath, David F. Moore, Johan van Lierop
  • Patent number: 8323755
    Abstract: Nematic liquid crystal cells with positive dielectric anisotropy that include colloidal suspensions having nanoclusters (e.g., CdTe nanoclusters, CdSe nanoclusters) that include a pure monolayer of ligands are provided as well as methods of inducing Freedericksz transitions in the nematic liquid crystal cells and methods of controlling the alignment of a liquid crystal.
    Type: Grant
    Filed: February 22, 2010
    Date of Patent: December 4, 2012
    Assignee: University of Manitoba
    Inventors: Torsten Hegmann, Brandy Melissa Kinkead