Abstract: Embodiments of apparatus, compositions, methods, systems, and articles of manufacture are disclosed relating to the optimization and production of biological components for use in biohybrid photosensitive devices and systems and other applications. In some embodiments, biologically derived components are disclosed having properties and/or characteristics that are optimized for applications of interest relative to corresponding components derived from naturally occurring organisms. In some embodiments, properties and/or characteristics of biological components are optimized by subjecting organisms and/or populations thereof to forced adaptation.

Abstract: A system for non-invasively monitoring a stress level of a subject is presented. A sensor is configured to monitor an attribute of the subject. A housing is configured to removably attach to the subject, the housing includes a processor in communication with the sensor, the processor is configured to retrieve data from the sensor, and use the data retrieved from the sensor to determine a stress level of the subject.

Abstract: A system for non-invasively monitoring a stress level of a subject is presented. A sensor is configured to monitor an attribute of the subject. A housing is configured to removably attach to the subject, the housing includes a processor in communication with the sensor, the processor is configured to retrieve data from the sensor, and use the data retrieved from the sensor to determine a stress level of the subject.

Abstract: Apparatus, compositions, methods, and articles of manufacture are disclosed relating to the design and production of biological components and/or their incorporation in devices and systems, including biohybrid photosensitive devices and systems. In some embodiments, biological components include light antenna structures that collect light and emit Stokes-shifted light to a photoactive non-biological component. In some embodiments, the characteristics of biological components are engineered via force-adaptation of an organism or adaptive system. In some embodiments, biological components are modified by removing reaction centers or other structure not contributing to desired performance.

Abstract: Apparatus, compositions, methods, and articles of manufacture are disclosed relating to the design and production of biological components and/or their incorporation in devices and systems, including biohybrid photosensitive devices and systems. In some embodiments, biological components include light antenna structures that collect light and emit Stokes-shifted light to a photoactive non-biological component. In some embodiments, the characteristics of biological components are engineered via force-adaptation of an organism or adaptive system. In some embodiments, biological components are modified by removing reaction centers or other structure not contributing to desired performance.

Abstract: An improved method for the design and development of high performance hybrid devices having biological and nonbiological components. The biological component is used in hybrid constructs that may be nanostructures, given the small size of the biological parts. In one specific embodiment, chlorosomes of Chloroflexus aurantiacus (C. aurantiacus) enhance performance of a silicon photovoltaic cell. C. aurantiacus, strain J-10-f1, has the A.T.C.C. designation number 29366, having been deposited in July, 1976. Its chlorosomes are harvested and positioned in light communicating relation to a photoactive semiconductor. The chlorosomes react to light of a first wavelength by emitting light at a second wavelength to which the semiconductor electrically responds.

Abstract: An improved method for the design and development of high performance biologically-derived components for use in hybrid devices. The biologically-derived component is used in hybrid constructs that may be nanostructures, given the small size of the biological parts. Force adaptation is used to bring an organism from which the biologically-derived component is developed to provide such a component meeting a desired measure of performance. In one specific embodiment, chlorosomes of Chloroflexus aurantiacus (C. aurantiacus) enhance performance of a silicon photovoltaic cell. C. aurantiacus, strain J-10-f1, has the A.T.C.C. designation number 29366, having been deposited in July, 1976. Its chlorosomes are harvested and positioned in light communicating relation to a photoactive semiconductor.

Abstract: An improved method for the design and development of high performance hybrid devices having biologically-derived and nonbiological components and the hybrid devices so-designed and developed. A desired transfer function is determined for the biologically-derived component or components. The organism from which the biologically-derived component is derived is subjected to various environmental variables as it is grown. Organisms providing biologically-derived components having the desired transfer function are identified. The biologically-derived component is thereafter developed from organisms force adapted to cause the biologically-derived component transfer function to reach a goal or an acceptable measure. The biological component is used in hybrid constructs that may be nanostructures, given the small size of the biological parts. In one specific embodiment, force-adapted chlorosomes of Chloroflexus aurantiacus (C. aurantiacus) enhance performance of a silicon photovoltaic cell. The bacteria, C.

Abstract: An improved method for the design and development of high performance hybrid devices having biologically-derived and nonbiological components and the hybrid devices so-designed and developed. A desired figure of merit is determined for the biologically-derived component or components. The organism from which the biologically-derived component is derived is subjected to various environmental variables as it is grown. Organisms providing biologically-derived components having the desired figure of merit are identified. The biologically-derived component is thereafter developed from organisms force adapted to cause the biologically-derived component figure of merit to reach a goal or an acceptable measure. The biological component is used in hybrid constructs that may be nanostructures, given the small size of the biological parts. In one specific embodiment, force-adapted chlorosomes of Chloroflexus aurantiacus (C. aurantiacus) enhance performance of a silicon photovoltaic cell. The bacteria, C.

Abstract: An improved method for the design and development of high performance hybrid devices having biological and nonbiological components. The biological component is used in hybrid constructs that may be nanostructures, given the small size of the biological parts. In one specific embodiment, chlorosomes of Chloroflexus aurantiacus (C. aurantiacus) enhance performance of a silicon photovoltaic cell. C. aurantiacus, strain J-10-f1, has the A.T.C.C. designation number 29366, having been deposited in July, 1976. Its chlorosomes are harvested and positioned in light communicating relation to a photoactive semiconductor. The chlorosomes react to light of a first wavelength by emitting light at a second wavelength to which the semiconductor electrically responds.

Abstract: An improved method for the design and development of high performance hybrid devices having biological and nonbiological components. A figure of merit is developed for the biological component or components. The component is subjected to various environmental variables as it or its biological source organism is grown. The biological component is force adapted to cause its figure of merit to reach a goal or an acceptable measure. The biological component is used in hybrid constructs that may be nanostructures, given the small size of the biological parts. In one specific embodiment, force-adapted chlorosomes of C. aurantiacus enhance performance of a silicon photovoltaic cell. The bacteria, Chloroflexus aurantiacus (C. aurantiacus), strain J-10-fl, has the A.T.C.C. designation number 29366, having been deposited in July, 1976.