INTERACTION OF BIOSILICA BASED BIOMATERIAL FROM TROPICAL MARINE DIATOM WITH HUMAN BLOOD PROTEINS
Recent research shows that biosilica from diatomaceous microalgae can be used as biomaterials, for example, biomaterials that make up bone implants, dental implants, drug delivery systems, and many more. However, in the body, the interaction of blood and biomaterials can trigger a series of co...
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| Format: | Final Project |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/81361 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Recent research shows that biosilica from diatomaceous microalgae can be used as
biomaterials, for example, biomaterials that make up bone implants, dental implants, drug
delivery systems, and many more. However, in the body, the interaction of blood and
biomaterials can trigger a series of complex events such as adsorption or coagulation of
proteins, as well as adhesion or platelet aggregation. Therefore, this research aims to study the
interaction profile between biosilica from diatoms and human blood proteins to develop
biosilica as a compatible biomaterial. In this study, cultivation of Navicula salinicola NLA
diatoms isolated from the Thousand Islands of Indonesia was carried out, followed by the
process of extraction until pure biosilica was obtained as evidenced by FTIR spectrum analysis.
The cultivation results showed that the initial cell density of Navicula salinicola NLA was
700,000 cells/mL which increased to 5,390,000 cells/mL after 12 days of growing in modified
seawater media. The obtained biomass has a productivity of 5.34 g/L of culture. From the
biomass, biosilica was successfully extracted with a productivity of 49.41 mg/L of culture.
Biosilica is then mixed with human serum albumin (HSA) or human blood plasma to investigate
the protein adsorption process. The results showed that the occurrence of protein adsorption
follows pseudo-first-order kinetics. Thermodynamically, the adsorption of blood proteins by
biosilica follows the Freundlich, Sips, and Temkin adsorption isotherm model. In addition, two
different diatom species were also compared, namely Navicula salinicola NLA (pennate form
diatom) and Cyclotella striata TBI (centrate form diatom). Based on the value of adsorption
capacity at equilibrium (qe) and percentage of adsorbed protein, HSA is more effectively
adsorbed by N. salinicola diatoms. At low protein concentrations, N. salinicola can absorb up
to ±99% protein (qe = 101.26 mg/g), and C. striata up to ±40% protein (qe = 42.21 mg/g). At
high protein concentrations, N. salinicola can absorb up to ±62% (qe = 379.15 mg/g), and C.
striata up to ±56% (qe = 311.14 mg/g). Similar to albumin adsorption, human blood plasma is
also more effectively adsorbed by N. salinicola diatoms (qe = 840.51 mg/g) compared to C.
striata (qe = 770.77 mg/g). |
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