ACCURACY IMPROVEMENT FOR EVALUATING 3D SILK FIBROIN SCAFFOLD MICROARCHITECTURE USING MICROCOMPUTED TOMOGRAPHY
Performance of direct-dissolution salt-leached silk fibroin scaffold for tissue engineering is heavily influenced by its microarchitecture as it affects cell – scaffold interaction. It is very important to evaluate microarchitecture parameters, which are pore size, porosity, wall thickness, pore...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/42442 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Performance of direct-dissolution salt-leached silk fibroin scaffold for tissue
engineering is heavily influenced by its microarchitecture as it affects cell –
scaffold interaction. It is very important to evaluate microarchitecture parameters,
which are pore size, porosity, wall thickness, pore interconnectivity, and specific
surface area, three dimensionally so that it is representative. Microarchitecture
measurement has been done but with inaccurate method as the image resulting
from Microcomputed Tomography (micro-CT) lacks contrast and the specimen
evaluated was still too thin. This experiment was aimed to improve the accuracy of
scaffold evaluation using micro-CT by determination of suitable threshold setting
and the minimum specimen thickness of 3D evaluation of silk fibroin scaffold
microarchitecture. Threshold was determined by comparing micro-CT images from
scaffolds made with salt particles of size 158 ?m and 503 ?m to their respective
scanning electron microscopy (SEM) results using ImageJ. Minimum specimen
thickness was determined from the relationship between average pore sizes
measured for every specimen thickness, evaluated using CTAn. These two
parameters were then used to measure other scaffold microarchitecture parameters.
From the experiment, the threshold was determined to be Threshold = (0.061 x salt
particle size) – 4.62. Ratio of minimum specimen thickness to scaffold pore size
used to evaluate scaffold is 6:1. Generally, it was found that increasing the scaffold
specimen thickness increases average pore size measurement. By increasing
threshold, increase happened in porosity and interconnectivity measurement while
decrease happened in wall thickness and specific surface area measurement.
Accuracy of microarchitecture measurement was improved for all parameters
except for scaffold wall thickness.
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