Volume 12

  • No. 12 December 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 11 November 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 10 October 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 9 September 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 8 August 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 7 July 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 6 June 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 5 May 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 3 March 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 2 February 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.

  • No. 1 January 2015

    Cover image supplied by James C. Weaver, Catherine S. Spina, James J. Collins, and Donald E. Ingber, from the Wyss Institute, Harvard University, Cambridge, MA, USA. The image shows a polychromatic scanning electron micrograph of a bisected heart of an E15.5 mouse. Using a radial array of electron detectors, the electron scatter field can be deconstructed from the surface of a sample. The signals from each detector can then be recombined to create a colour-coded topographic reconstruction of the sample surface, with the resulting image shown here clearly illustrating the 3D external and internal architecture of the heart.