Results : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [2]
in which ρ = density, h = height, ω = angular velocity and r = radius.
Figure 3 shows the respective physical force and its dependence on a bigger radius and higher rotational speed. The results of this study indicate that the centrifugal force represents only a little proportion of effective forces. Hence, the centrifugal forces’ impacts on the tested cells are considered to be insignificant.
Cells were subjected to 24 h of fluid flow rotations at a speed level of 200 rpm. The exposed test cells within the new FSS chamber changed their orientation in accordance with the flow direction. Microscopic evaluation was conducted via a random screening at the peripheral site (2.5-cm radial distance) within a predefined area of interest (0.2 cm × 0.2 cm) through cell counting (at least n = 40 cells/region of interest) and morphological cell characterisation. The FSS-triggered effect was demonstrated as cells realigned themselves towards the flow direction, whereby only cells with an aspect ratio greater than 2:1 were included. To assess the alterations taking place inside the cell body, osteoblast cells were treated with a fluorescence stain to visualise actin fibres. In addition, the cells were split into two groups; the first group (n = 5) remained untreated, without any impact of shear stress (Fig. 4) while the cells in the second group (n = 5) underwent a 24-h rotational impact with 8.35 dyn/cm2 shear force. All tests and analysis were repeated at least six times. The cells showed a reproducible (n > 6) realignment of the actin cytoskeleton towards the fluid flow direction (Fig. 5), whereas the actin fibres of the untreated group showed random orientations. Findings were termed a trend if more than 50% of all screened cells (n > 21 cells) underwent reorientation.
Serial posts:
- Abstract : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up
- Background : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [1]
- Background : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [2]
- Methods : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [1]
- Methods : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [2]
- Results : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [1]
- Results : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [2]
- Discussion : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [1]
- Discussion : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [2]
- Discussion : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [3]
- Conclusions : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up
- Abbreviations : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up
- References : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [1]
- References : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [2]
- References : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [3]
- References : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [4]
- Acknowledgements : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up
- Author information : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [1]
- Author information : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up [2]
- Rights and permissions : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up
- About this article : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up
- Table 1 Listing of the single components of the flow chamber together with manufacturers’ data : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up
- Table 2 Listing of the culture media and additives together with manufacturers’ data : Cellular fluid shear stress on implant surfaces—establishment of a novel experimental set up
- Fig. 1. Three-dimensional illustration (a–e) and photography (f) of the experimental setup with the components marked numerical. a1 Lower petri dish (s’ bottom serving as the lower plate); 2 Rotating glass panel [60 mm diameter (cell bearing)]; 3 Titanium axis. b4 Liquid medium (red). c5 Reversed upper petri dish. d6 Gearwheel with set screw. e7 Closing; 8 Electronic motor device and adjusting ring with additional set screw : Cellular fluid shear stress on implant
- Fig. 2. Side view of a computerized simulation, showing the flow chambers’ lower compartment and the flow profile in between the two plates; shearing gap and bottom plate are shown on the left side; rotation speed = 200 rpm; colour code bar (left edge) showing shear force values [Pa] [1 Pa = 10 dyn/cm2]; flow direction presented by arrows : Cellular fluid shear stress on implant
- Fig. 3. Diagram for visualisation of the calculation of shear stress rates taking into account the centrifugal force and the glass plates’ dimensions. For example, at a distance of 25 mm from the centre of the upper plate, the shear forces’ value is 8.33 dyn/cm2, together with an additional centrifugal force that has a value of 0.55 dyn/cm2 : Cellular fluid shear stress on implant
- Fig. 4. Randomly orientated osteoblasts without influence of rotation (phallacidin fluorescence staining). On the left side with 200× and on the right side with 400× magnification. The white X on the coloured circle marks the location upon the plate where the osteoblasts were located. The red X marks the centre of the plate : Cellular fluid shear stress on implant
- Fig. 5. Osteoblasts with an orientation tendency after 24 h of rotation (phallacidin fluorescence staining). On the left side with 200× and on the right side with 400× magnification. The yellow arrows show the orientation of the cells. The red arched arrow within the coloured circle shows the direction of rotation. The dashed white line oriented to the right stands for the resulting centrifugal force. The dashed white line pointing upwards shows the direction of the resulting flow resistance. The solid white arrow stands for the vectorial sum of the abovementioned forces : Cellular fluid shear stress on implant