Seungeun Oh scite author profile

We report a technique for quantitative three-dimensional (3D) mapping of refractive index in live cells and tissues using a phase-shifting laser interferometric microscope with variable illumination angle. We demonstrate tomographic imaging of cells and multicellular organisms, and time-dependent changes in cell structure. Our results will permit quantitative characterization of specimen-induced aberrations in high-resolution microscopy and have multiple applications in tissue light scattering.

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Multiple phases of chondrocyte enlargement underlie differences in skeletal proportions

Cooper

Sung

et al. 2013

Nature

343

312

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Even a casual pass through the great halls of mammals in the world’s natural history museums highlights the wide diversity of skeletal proportions that allow us to distinguish between species even when reduced to their calcified components. Similarly each individual is comprised of a variety of bones of differing lengths. The largest contribution to the lengthening of a skeletal element, and to the differential elongation of elements, comes from a dramatic increase in the volume of hypertrophic chondrocytes in the growth plate as they undergo terminal differentiation1–7. Despite this recognized importance, the mechanisms of chondrocyte volume enlargement have remained a mystery8–11. Here we use quantitative phase microscopy12 to show that chondrocytes undergo three distinct phases of volume increase, including a phase of massive cell swelling in which the cellular dry mass is significantly diluted. In light of the tight fluid regulatory mechanisms known to control volume in many cell types13, this stands as a remarkable mechanism for increasing cell size and regulating growth rate. It is, however, the duration of the final phase of volume enlargement by proportional dry mass increase at low density that varies most between rapidly and slowly elongating growth plates. Moreover, we find that this third phase is locally regulated through an Insulin-like Growth Factor-dependent mechanism. This study provides a framework for understanding how skeletal size is regulated and for exploring how cells sense, modify, and establish a volume set point.

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Dynamics extracted from fixed cells reveal feedback linking cell growth to cell cycle

Kafri

Levy

Ginzberg

et al. 2013

Nature

233

298

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Biologists have long been concerned about what constrains variation in cell size; yet, progress on this question has been slow and stymied by experimental limitations1. We describe a new method, ergodic rate analysis (ERA), that uses single cell measurements of fixed steady-state populations to accurately infer the rates of molecular events, including rates of cell growth. ERA exploits the fact that the number of cells in a particular state is related to the average transit time through that state2. With this method, one can calculate full time trajectories of any feature that can be labeled fixed cells, for example levels of phospho-proteins or total cellular mass. Using ERA we find evidence for a size-discriminatory process at the G1/S transition that acts to decrease cell-to-cell size variation.

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Seungeun Oh

Tomographic phase microscopy

Multiple phases of chondrocyte enlargement underlie differences in skeletal proportions

Dynamics extracted from fixed cells reveal feedback linking cell growth to cell cycle

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