Abstract:Three-dimensional (3-D) cell cultures are beneficial models for mimicking the complexities of in vivo tissues, especially in tumour studies where transport limitations can complicate response to cancer drugs. 3-D optical microscopy techniques are less involved than traditional embedding and sectioning, but are impeded by optical scattering properties of the tissues. Confocal and even two-photon microscopy limit sample imaging to approximately 100-200 lm depth, which is insufficient to image hypoxic spheroid co… Show more
“…The results demonstrated that the method induces a minimal reduction of the size of the spheroids, that is, the ratio of spheroids area before and after the clearing was 1.02 (Grist et al, 2016). The results demonstrated that the method induces a minimal reduction of the size of the spheroids, that is, the ratio of spheroids area before and after the clearing was 1.02 (Grist et al, 2016).…”
Section: See Deep Brainmentioning
confidence: 90%
“…The results demonstrated that the method induces a minimal reduction of the size of the spheroids, that is, the ratio of spheroids area before and after the clearing was 1.02 (Grist et al, 2016). An analysis of the average FUCCI fluorescence intensity as a function of penetration depth into the sample demonstrated that the SeeDB method allowed to image the spheroids at depths greater than 250 μm, while the imaging of noncleared spheroid was limited to about 150 μm (Grist et al, 2016). The transparency was slightly improved since the light transmittance increased to about 5.5% in the cleared spheroids (Grist et al, 2016).…”
Section: See Deep Brainmentioning
confidence: 96%
“…This reduction is dependent on the flow rate used in the microfluidic channel, that is, higher flow rates lead to higher shrinkage, which may be related to the fluidic compressive forces or to the osmotic pressure. Nevertheless, the authors also observed that SeeDB solution increased the green fluorescence intensity of the spheroids (Grist et al, 2016), which was attributed to the formation of Maillard reaction products (Berke, Miola, David, Smith, & Price, 2016 occurred as a consequence of the clearing process (Boutin & Hoffman-Kim, 2015). An analysis of the average FUCCI fluorescence intensity as a function of penetration depth into the sample demonstrated that the SeeDB method allowed to image the spheroids at depths greater than 250 μm, while the imaging of noncleared spheroid was limited to about 150 μm (Grist et al, 2016).…”
Section: See Deep Brainmentioning
confidence: 97%
“…These methods aim to reduce the light-scattering phenomenon in the biological samples, rendering samples with increased transparency that promotes deeper imaging, as well as the cells structural and functional analysis (discussed hereafter). In this way, the light penetration is usually limited to a range of 100-150 μm, which is insufficient for the imaging of the spheroids whole volume (Grist, Nasseri, Poon, Roskelley, & Cheung, 2016;Richardson & Lichtman, 2015). This phenomenon promotes light scattering and it is the main cause of tissues opacity.…”
Spheroids have emerged as in vitro models that reproduce in a great extent the architectural microenvironment found in human tissues. However, the imaging of 3D cell cultures is highly challenging due to its high thickness, which results in a lightscattering phenomenon that limits light penetration. Therefore, several optical clearing methods, widely used in the imaging of animal tissues, have been recently explored to render spheroids with enhanced transparency. These methods are aimed to homogenize the microtissue refractive index (RI) and can be grouped into four different categories, namely (a) simple immersion in an aqueous solution with high RI;(b) delipidation and dehydration followed by RI matching; (c) delipidation and hyperhydration followed by RI matching; and (d) hydrogel embedding followed by delipidation and RI matching. In this review, the main optical clearing methods, their mechanism of action, advantages, and disadvantages are described. Furthermore, the practical examples of the optical clearing methods application for the imaging of 3D spheroids are highlighted.
K E Y W O R D Simaging, light scattering, optical clearing, optical microscopy, spheroids.
“…The results demonstrated that the method induces a minimal reduction of the size of the spheroids, that is, the ratio of spheroids area before and after the clearing was 1.02 (Grist et al, 2016). The results demonstrated that the method induces a minimal reduction of the size of the spheroids, that is, the ratio of spheroids area before and after the clearing was 1.02 (Grist et al, 2016).…”
Section: See Deep Brainmentioning
confidence: 90%
“…The results demonstrated that the method induces a minimal reduction of the size of the spheroids, that is, the ratio of spheroids area before and after the clearing was 1.02 (Grist et al, 2016). An analysis of the average FUCCI fluorescence intensity as a function of penetration depth into the sample demonstrated that the SeeDB method allowed to image the spheroids at depths greater than 250 μm, while the imaging of noncleared spheroid was limited to about 150 μm (Grist et al, 2016). The transparency was slightly improved since the light transmittance increased to about 5.5% in the cleared spheroids (Grist et al, 2016).…”
Section: See Deep Brainmentioning
confidence: 96%
“…This reduction is dependent on the flow rate used in the microfluidic channel, that is, higher flow rates lead to higher shrinkage, which may be related to the fluidic compressive forces or to the osmotic pressure. Nevertheless, the authors also observed that SeeDB solution increased the green fluorescence intensity of the spheroids (Grist et al, 2016), which was attributed to the formation of Maillard reaction products (Berke, Miola, David, Smith, & Price, 2016 occurred as a consequence of the clearing process (Boutin & Hoffman-Kim, 2015). An analysis of the average FUCCI fluorescence intensity as a function of penetration depth into the sample demonstrated that the SeeDB method allowed to image the spheroids at depths greater than 250 μm, while the imaging of noncleared spheroid was limited to about 150 μm (Grist et al, 2016).…”
Section: See Deep Brainmentioning
confidence: 97%
“…These methods aim to reduce the light-scattering phenomenon in the biological samples, rendering samples with increased transparency that promotes deeper imaging, as well as the cells structural and functional analysis (discussed hereafter). In this way, the light penetration is usually limited to a range of 100-150 μm, which is insufficient for the imaging of the spheroids whole volume (Grist, Nasseri, Poon, Roskelley, & Cheung, 2016;Richardson & Lichtman, 2015). This phenomenon promotes light scattering and it is the main cause of tissues opacity.…”
Spheroids have emerged as in vitro models that reproduce in a great extent the architectural microenvironment found in human tissues. However, the imaging of 3D cell cultures is highly challenging due to its high thickness, which results in a lightscattering phenomenon that limits light penetration. Therefore, several optical clearing methods, widely used in the imaging of animal tissues, have been recently explored to render spheroids with enhanced transparency. These methods are aimed to homogenize the microtissue refractive index (RI) and can be grouped into four different categories, namely (a) simple immersion in an aqueous solution with high RI;(b) delipidation and dehydration followed by RI matching; (c) delipidation and hyperhydration followed by RI matching; and (d) hydrogel embedding followed by delipidation and RI matching. In this review, the main optical clearing methods, their mechanism of action, advantages, and disadvantages are described. Furthermore, the practical examples of the optical clearing methods application for the imaging of 3D spheroids are highlighted.
K E Y W O R D Simaging, light scattering, optical clearing, optical microscopy, spheroids.
“…The trapping mechanisms to load samples within the device vary depending on the design (Fig. 1A) and can combine many mechanisms studied by different authors, such as i) sedimentation trapping, where waiting for the tissue to settle into an extrusion from a channel traps it 7–10 ; ii) resistive trapping, which exploits preferential flow to guide samples into traps 11–16 ; iii) inertial trapping, which uses focusing flows or sharp turns to trap samples in channel recesses 17–19 ; iv) dielectrophoretic trapping, where the difference in permittivity between the fluid and tissue is exploited to trap it in an electric field 20, 21 ; v) and open-microfluidic channel networks, which create hanging droplets in which samples are trapped or synthesized 22, 23 .Figure 1Basic MST designs: ( A ) MST operation with schematics of different trapping mechanisms: resistive, dielectrophoretic, inertial and sedimentation trapping; blue axis is parallel to gravity. The picture of the western hemisphere of earth on a transparent background was solely created by NASA and is in the public domain in the United States.…”
This work focuses on modelling design and operation of “microfluidic sample traps” (MSTs). MSTs regroup a widely used class of microdevices that incorporate wells, recesses or chambers adjacent to a channel to individually trap, culture and/or release submicroliter 3D tissue samples ranging from simple cell aggregates and spheroids, to ex vivo tissue samples and other submillimetre-scale tissue models. Numerous MST designs employing various trapping mechanisms have been proposed in the literature, spurring the development of 3D tissue models for drug discovery and personalized medicine. Yet, there lacks a general framework to optimize trapping stability, trapping time, shear stress, and sample metabolism. Herein, the effects of hydrodynamics and diffusion-reaction on tissue viability and device operation are investigated using analytical and finite element methods with systematic parametric sweeps over independent design variables chosen to correspond to the four design degrees of freedom. Combining different results, we show that, for a spherical tissue of diameter d < 500 μm, the simplest, closest to optimal trap shape is a cube of dimensions w equal to twice the tissue diameter: w = 2d. Furthermore, to sustain tissues without perfusion, available medium volume per trap needs to be 100× the tissue volume to ensure optimal metabolism for at least 24 hours.
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