Back Cover: J. Biophotonics 1/2012

## Abstract Raman spectroscopy has been used in this study to obtain biochemical fingerprint patterns of collagen fibers in native aortic heart valve tissues. Using this non‐contact screening tool, we were able to monitor the increasing damage of collagen fibers due to enzymatic treatment or cryopr

## Abstract Three‐dimensional position and orientation control of rodshaped __B. subtilis__ with holographic optical tweezers. (Picture: F. Hörner et al., see also pp. 468–475 in this issue)

Raman spectroscopy has been used in this study to obtain biochemical fingerprint patterns of collagen fibers in native aortic heart valve tissues. Using this non-contact screening tool, we were able to monitor the increasing damage of collagen fibers due to enzymatic treatment or cryopreservation.

## Abstract Development of the posterior lateral line in a zebrafish embryo. Upper row: embryo 30 hpf, showing the migrating primordium and a deposited proneuromast. Second row, left: higher magnification image of a primordium (right) and proneuromast (left), visualized with membrane‐tagged eGFP. S

## Abstract Left panel: Photomicrograph, at 40× magnification, of a 1 × 1 mm stained section of axillary lymph node from a sentinel lymph node recession. The pink areas are due to the capsule, and the dark purple areas to lymphocytes. Right panel: Overlay of areas identified to contain abnormal tis

## Abstract Histological image of HE stained skin sample after injection of 30%‐glycerol (top left), bruised skin classified by spectral angle mapping (top right), transversal optically sectioned ex‐vivo skin sample of healthy dermis, imaged using TPEF (a), SHG (b), and the merge between the two im