Towards high resolution optical imaging of beta cells in vivo

Endocrine beta cells produce and release insulin in order to tightly regulate glucose homeostasis and prevent metabolic pathologies such as Diabetes Mellitus. Optical imaging has contributed greatly to our current understanding of beta cell structure and function. In vitro microscopy of beta cell lines has revealed the localization of molecular components in the cell and more recently their dynamic behavior. In cultured islets, interactions of beta cells with other islet cells and the matrix as well as paracrine and autocrine signaling or reaction to nutrients have been studied. Lastly, microscopy has been performed on tissue sections, visualizing the islets in an environment closer to their natural surroundings. In most efforts to date, the samples have been isolated for investigation and hence have by definition been divorced from their natural environments and deprived of vascularization and innervations. In such a setting the beta cells lack the metabolic information that is primordial to their basic function of maintaining glucose homeostasis. We review optical microscopy; its general principles, its impact in decoding beta cell function and its recent developments towards the more physiologically relevant assessment of beta cell function within the environment of the whole organism. This requires both large imaging depth and fast acquisition times. Only few methods can achieve an adequate compromise. We present extended focus Optical Coherence Microscopy (xfOCM) as a valuable alternative to both confocal microscopy and two photon microscopy (2PM), and discuss its potential in interpreting the mechanisms underlying glucose homeostasis and monitoring impaired islet function.

Definition of in Vitro Microenvironments to Characterize and Control Pancreatic Progenitor Expansion and Differentiation

Chiara Greggio

The pancreas plays a central role in metabolism. The exocrine pancreas, composed of ductal and acinar cells, secretes and delivers digestive enzymes into the duodenum where they contribute to food digestion. The endocrine pancreas, constituted by the islets of Langerhans, secretes hormones in the blood to control glucose levels. In particular, insulin is the hormone produced by β-cells that instructs the peripheral tissues to uptake circulating glucose. Diabetes mellitus is a heterogeneous disease characterized by deregulated glucose homeostasis due to an impaired insulin function. The advancements in clinical practice have made of diabetes a chronic, instead of a lethal, disease; yet no definitive cure is available. Beta-cell transplantation offers promising results, especially for type 1 diabetes where β-cells are selectively eliminated by an autoimmune attack. Unfortunately its application suffers from the scarcity of transplantable pancreas/islets from cadaveric donors. Human embryonic stem cells (ESCs) or induced pluripotent stem cells (iPSCs) would constitute unlimited sources of transplantable β-cells, but the available differentiation protocols are not yet optimal, especially with regards to the numbers and the functionality of the generated β-cells. It is anticipated that a stepwise protocol would succeed in generating mature β-cells in vitro if it is capable of fully mimicking the embryonic development of these cells. Many aspects of pancreatic organogenesis have been elucidated and could serve as a guide for driving the commitment to β-cells. Unfortunately, pancreatic progenitors in vitro do not behave as in the intricate context of an embryo. This severely limits both the understanding of pancreatic development at the single-cell level and our ability in manipulating the process. The aim of our work was to develop in vitro methodologies to sustain pancreatic progenitor culture and expansion and to establish conditions to manipulate their progeny. To this aim, we combined an informed approach based on developmental biology and an empirical one. We first observed that pancreatic epithelial explants from embryonic day 10.5 mice could be cultured in presence of Matrigel™ and exogenous FGFs even in the absence of the mesenchyme that normally surrounds the epithelium. Notably, the removal of mesenchyme did not affect the endocrine commitment pattern of pancreatic progenitors. We then defined culture conditions allowing for the expansion of dissociated embryonic pancreatic progenitors in a three-dimensional Matrigel™-based environment. Under these conditions, progenitors proliferated and self-organized to generate pancreatic organoids containing both progenitors and differentiated cells, mostly exocrine, after 7 days of culture. When grafted into recipient pancreatic explants, the cultured progenitors contributed to the three epithelial pancreatic lineages (ductal, endocrine, acinar), integrating seamlessly into the endogenous cellular network. Thus, cultured progenitors retained their potential to differentiate into endocrine cells, but expressed it only in the appropriate niche. Subsequent removal of single components from the culture system led to the identification of some essential requirements for the maintenance/expansion of dissociated pancreatic progenitors, such as a strong FGF signaling and the Rho-associated kinase (ROCK) inhibitor Y-27632. In addition to this, we observed that only small clusters of pancreatic progenitors, but not single cells, were able to generate pancreatic organoids, suggesting a pivotal role for intercellular signaling in progenitor maintenance and expansion. By manipulating the components of the medium, we could affect fate commitment. In particular, the removal of FGF1 increased the yield of endocrine cells generated in vitro. In our search for a full control over the in vitro niche, we explored chemically defined matrices to replace Matrigel™. We showed that pancreatic progenitors could be cultured on laminin-functionalized hydrogels, although less efficiently than in Matrigel™. Moreover, differentiation into exocrine and endocrine cells occurred spontaneously under these conditions. By comparing Matrigel™, hydrogel microwells and two-dimensional culture systems, we uncovered the importance of a tridimensional architecture for pancreatic progenitor maintenance. We showed that pancreatic progenitors lost their identity as they flattened onto 2D surfaces, whereas 3D culture systems maintained the epithelial character of pancreatic progenitors and allowed the acquisition of apical polarization. To conclude, our work provides the first detailed characterization of in vitro culture systems for expansion and manipulation of dissociated embryonic pancreatic progenitors. Further implementation will hopefully allow the establishment of a fully-defined in vitro niche for developing pancreas with potential fundamental implications for the expansion of ES-derived pancreatic progenitors and their differentiation into functional β-cells.

EPFL2011

In vivo imaging of murine endocrine islets of Langerhans with extended-focus optical coherence microscopy

Michael Friedrich, Joan Goulley, Anne Grapin-Botton, Theo Lasser, Rainer Leitgeb, Martin Villiger

Aims/hypothesis Structural and functional imaging of the islets of Langerhans and the insulin-secreting beta cells represents a significant challenge and a long-lasting objective in diabetes research. In vivo microscopy offers a valuable insight into beta cell function but has severe limitations regarding sample labelling, imaging speed and depth, and was primarily performed on isolated islets lacking native innervations and vascularisation. This article introduces extended-focus optical coherence microscopy (xfOCM) to image murine pancreatic islets in their natural environment in situ, i.e. in vivo and in a label-free condition. Methods Ex vivo measurements on excised pancreases were performed and validated by standard immunohistochemistry to investigate the structures that can be observed with xfOCM. The influence of streptozotocin on the signature of the islets was investigated in a second step. Finally, xfOCM was applied to make measurements of the murine pancreas in situ and in vivo. Results xfOCM circumvents the fundamental physical limit that trades lateral resolution for depth of field, and achieves fast volumetric imaging with high resolution in all three dimensions. It allows label-free visualisation of pancreatic lobules, ducts, blood vessels and individual islets of Langerhans ex vivo and in vivo, and detects streptozotocin-induced islet destruction. Conclusions/interpretation Our results demonstrate the potential value of xfOCM in high-resolution in vivo studies to assess islet structure and function in animal models of diabetes, aiming towards its use in longitudinal studies of diabetes progression and islet transplants.

Springer Verlag2009

Extended Focus Optical Coherence Microscopy

Martin Villiger

Optical coherence tomography (OCT) is an interferometric imaging technique that can provide depth resolved cross-sectional views of biological tissue. OCT employs light with low temporal and yet high spatial coherence. The sample is illuminated point by point and raster scanned in the lateral directions. Part of the incident light is back-scattered by differences in the tissue refractive index and combined with a strong reference signal. The detection in the Fourier, or frequency domain (FDOCT), separates the interference signal spectrally and records the resulting pattern with a line camera. Processing of this pattern extracts the sample structure along the axial direction but without axial scanning and in parallel with high resolution of 2-3 µm. The interferometric detection conveys a very high sensitivity that allows imaging several hundred micrometers deep into the tissue. A single two dimensional scan thus can extract the three dimensional structure of the object, resulting in very high volume acquisition rates and offering an exceptional speed advantage over other optical imaging methods. Combined with its ability to measure an intrinsic sample property without the need of adding extrinsic labels or contrasting agents, FDOCT has become a confirmed tool for minimally invasive in vivo measurements and comprehensive volumetric imaging. While the axial resolution in OCT is defined by the coherence length of the employed light source, it is the optical focusing that specifies the resolution in the lateral direction, which reaches in general only approximately 10 µm. To improve the resolution, classical optical coherence microscopy (OCM) uses higher numerical apertures. However, this implies a reduction of the lateral dimension of the focal spot which leads to a dramatic decrease in the depth of field (DOF). This imposes a severe limitation on FDOCT's parallel depth extraction. Therefore, the motivation behind this thesis work was to circumvent the compromise between the lateral resolution and the depth of field by engineering an extended focal volume (xf). Combining FDOCT's assets of speed and sensitivity with the high lateral resolution of microscopy provided a very promising tool for rapid in vivo imaging at close to cellular resolution. To study the mechanisms limiting the DOF and to investigate what impact they have on the tomogram reconstruction process, we developed a model for image formation in FDOCT. Generally, the tomogram is reconstructed from the two dimensional interference patterns in the individual spectral channels of the detection. By making use of the coherent transfer functions (CTF), the spatial frequency content made accessible by each channel, was analyzed. This provided a novel perspective on the entire tomogram formation. We were able to show that the out-of-focus structures suffer from two signal degrading mechanisms. First, a de-focusing effect, induced by additional phase arguments in the spatial frequency domain provokes a lateral blurring. Second, the setup's reduced transmission efficiency for out-of-focus structures results in an amplitude scaling. The application of the CTF enabled us to illustrate the intrinsic link between these two effects and to develop optical design strategies and novel configurations to circumvent their detrimental impact on the quality of the tomogram. It is known that with the use of a conical lens, it is possible to produce a so-called diffraction-less beam. Close to the optical axis, the radial envelope of its field amplitude follows a Bessel function of order zero and is maintained upon propagation over a long axial range. We could show that a combination of such a Bessel-like beam with a Gaussian detection indeed limits both the de-focusing and amplitude scaling phenomenon, all the while improving the lateral resolution. The price to pay is a reduced signal amplitude also at the in-focus position, as compared to a Gaussian focal volume of a classical confocal setting. Another possibility is to combine the Bessel-like illumination with a Bessel-like detection, although with differently spaced side lobes in its envelope. These different combinations were evaluated both analytically and with computer simulations. Several of the proposed solutions were implemented in practice to confirm the theoretical predictions. Considering that the theoretical analysis was performed in the spatial frequency domain and in terms of the CTF, the corresponding system parameters had to be measured. Lacking an adequate technique, we developed and validated a method which derived characteristic parameters of the optical system's CTF from the measurement of a simple rubber surface. The tomogram of this sample consists of a fully developed speckle field. Although generally disfavored for degrading the tomogram quality, in this case the speckle shape provided information on the system characteristics because it was imposed by the illumination and detection apertures of the system in question. Since the principal interest behind the development of xfOCM was its amenability to live imaging, we used this novel concept to visualize individual islets of Langerhans in a mouse pancreas. These endocrine islets are assemblies of insulin-secreting beta cells contained within the exocrine tissue of the organ. They are of primary importance in the research on diabetes, but their large diversity in size, down to the micrometer scale, and their localization in the pancreas have so far hindered their observation in vivo. To meet the conditions for successful live imaging, we implemented the xfOCM into a specially designed setup that could provide enough mechanical robustness to allow for measurements over long periods. In addition, the set up was equipped with a fast beam scanning device to achieve high volume acquisition rates. The signal processing and the user interface were conceived in such a way that they offered a rapid visualization of the tomograms, providing an instantaneous feedback and facilitating sample handling. With the developed architecture we achieved label-free in vivo visualization of pancreatic lobules, ducts, blood vessels and individual islets of Langerhans and could demonstrate the potential of the xfOCM in diabetes research for high resolution studies on live animals. Besides the aim of an extended focal volume, the control over the design of the CTF also enabled the realization of a dark field configuration. Signals with low spatial frequencies are suppressed in this configuration, which enabled the measurement of the weak scattering signature of near transparent live cell samples. In conclusion, this thesis provides a better understanding of the image formation involved in the FDOCT. Several strategies to increase the trade-off between lateral resolution and DOF were proposed and validated experimentally. The suitability and potential of this approach for small animal in vivo imaging was demonstrated in the context of a relevant biological question.