TY - GEN

T1 - Evaluation of a model for deep tissue optogenetic stimulation

AU - Johannsmeier, Sonja

AU - Wenzel, Johannes

AU - Torres-Mapa, Maria L.

AU - Junge, Sebastian

AU - Sasse, Philipp

AU - Ripken, Tammo

AU - Heinemann, Dag

AU - Heisterkamp, Alexander

N1 - Funding information: This work is funded by the Federal Ministry of Education and Research, Germany, Grant no. 13N14085 and supported by the DFG Cluster of Excellence “Hearing4all” (EXC 1077/1).

PY - 2020/2/19

Y1 - 2020/2/19

N2 - In the past decade, in vivo models for optogenetic applications have gained importance, especially in the fields of cardiology and neuroscience. To reliably evoke the desired reactions while minimizing adverse effects, the stimulation power must be carefully adjusted. The relevant light intensity for cells in deeper layers of scattering tissue is not easily extrapolated from the power threshold of single cells. In this study, we evaluated a model for deep tissue optogenetic stimulation, using a heart-like cell line and tissue phantoms. Phantoms were fabricated from PDMS and titanium dioxide particles and possessed highly reproducible optical properties. Scattering and absorption coefficients were modeled to match those of realistic tissues. Since power of light traveling through tissues decays exponentially with respect to the scattering and absorption coefficients, the required input power was expected to increase exponentially by the same factor. To test this hypothesis, cells were stimulated through tissue phantoms of varying thickness with different modes of illumination. Cellular reactions revealed that the simplified assumptions were not sufficient to predict the input power required to reach the stimulation threshold. We provide a more comprehensive model to assess cellular reactions in scattering tissues a priori. This study has implications for the use of optogenetics in tissue models, organs and in vivo models as the outcomes can be transferred to different types of cells and tissues.

AB - In the past decade, in vivo models for optogenetic applications have gained importance, especially in the fields of cardiology and neuroscience. To reliably evoke the desired reactions while minimizing adverse effects, the stimulation power must be carefully adjusted. The relevant light intensity for cells in deeper layers of scattering tissue is not easily extrapolated from the power threshold of single cells. In this study, we evaluated a model for deep tissue optogenetic stimulation, using a heart-like cell line and tissue phantoms. Phantoms were fabricated from PDMS and titanium dioxide particles and possessed highly reproducible optical properties. Scattering and absorption coefficients were modeled to match those of realistic tissues. Since power of light traveling through tissues decays exponentially with respect to the scattering and absorption coefficients, the required input power was expected to increase exponentially by the same factor. To test this hypothesis, cells were stimulated through tissue phantoms of varying thickness with different modes of illumination. Cellular reactions revealed that the simplified assumptions were not sufficient to predict the input power required to reach the stimulation threshold. We provide a more comprehensive model to assess cellular reactions in scattering tissues a priori. This study has implications for the use of optogenetics in tissue models, organs and in vivo models as the outcomes can be transferred to different types of cells and tissues.

KW - Light diffusion

KW - Optogenetics

KW - Tissue phantoms

UR - http://www.scopus.com/inward/record.url?scp=85082501742&partnerID=8YFLogxK

U2 - 10.1117/12.2544837

DO - 10.1117/12.2544837

M3 - Conference contribution

AN - SCOPUS:85082501742

T3 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE

BT - Optogenetics and Optical Manipulation 2020

PB - SPIE

T2 - Optogenetics and Optical Manipulation 2020

Y2 - 1 February 2020 through 2 February 2020

ER -