Fish scale derived hydroxyapatite scaffold for bone tissue engineering

Mondal, Bittagopal; Mondal, Sudip; Mondal, Amita; Mandal, Nilrudra

doi:10.1016/j.matchar.2016.09.034

Cited by 68 publications

(26 citation statements)

References 28 publications

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“…HAp derived from high temperature sintering of fish scales [80,81], fish bone [82,83], bovine bone [84] and pig bone [85] have also been used for development of composite bone scaffolds. Thus it is seen that bioceramic HAp has been derived from a wide range of natural sources like corals, algae and shells and biowaste maerials like eggshells, scales and bones.…”

Section: Hap From Bones and Scalesmentioning

confidence: 99%

Naturally derived biomaterials for development of composite bone scaffold: A review

Barua

Deoghare

Deb

et al. 2018

IOP Conf. Ser.: Mater. Sci. Eng.

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E-mail: imon18enator@gmail.comAbstract. Over the last few decades, there has been an increasing demand of tissue engineered bone scaffolds as a substitute material for diseased or damaged bone segments. A variety of synthetic and natural biomaterials have been explored by researchers for development of composite scaffold. Naturally derived biomaterials have the advantages of immunomodulating, anti-toxic and biomimetic properties with the cellular environment in vivo, when compared to synthetic biomaterials. In this paper, different protein and polysaccharide based biomaterials used for developing composite bone scaffolds are reviewed. The properties of composite scaffolds developed from these biomaterials are highlighted. The study also includes different natural materials and biowastes which are used for deriving bioceramics for producing composite bone scaffolds. The overall study gives a brief idea on the importance of protein and polysaccharide based biomaterials and bioceramics for composite bone scaffold development and scope for future work in the field of naturally derived biomaterials.

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Section: Hap From Bones and Scalesmentioning

confidence: 99%

Naturally derived biomaterials for development of composite bone scaffold: A review

Barua

Deoghare

Deb

et al. 2018

IOP Conf. Ser.: Mater. Sci. Eng.

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“…5a) evidences a wide peak at 3 420 cm -1 corresponding to -O-H stretching vibrations of polymeric carbohydrates and overlapped stretching bands of -N-H groups in the collagen; and a wide and intense peak at 2 960 cm -1 , corresponding to -C-H stretches belonging to carbon skeletons. Furthermore, the raw material also exhibits peaks at 1 654 and 1 545 cm -1 , assigned to type-I and -II amide (typical of samples containing collagen); peaks at 1 440 and 871 cm -1 ,assigned to asymmetrical and out-of-plane stretching CO 3 2− ; and a peak at 1 026 cm -1 , corresponding to P-O stretches in PO 4 3- [5,19]. The FTIR spectra for HAp obtained by direct calcination (Fig.…”

Section: Oxidementioning

confidence: 99%

High temperature CO2 capture of hydroxyapatite extracted from tilapia scales

2017

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Hydroxyapatite (HAp) was obtained from tilapia scales by two extraction methods: direct calcination and acid-base treatment. The physicochemical characteristics of the obtained HAps were evaluated by thermogravimetric analysis, X-ray fluorescence, X-ray diffraction, scanning electron microscopy, surface area, infrared spectroscopy, and basicity measurement at 298 K by CO 2 -pulse titration. Furthermore, the CO 2 capture capacity of the solids at high temperature was also determined. Both methods showed the presence of a HAp phase although significant differences in the properties of the solids were found. The HAp obtained by direct calcination, exhibited a lower crystallinity and a greater surface area and basicity than the HAp obtained by the acid-base treatment. These features were correlated with the solid's CO 2 capture capacity. In this work, CO 2 capture capacity values for HAp yielded by calcination ranged from 2.5 to 3.2 mg CO 2 /g captured at 973 K, and for the acid-base treatment-derived HAp, CO 2 capture capacity values between 1.2 to 2.5 mg CO 2 /g were recorded. These results reveal the potential of HAps extracted from tilapia scales as solids with high CO 2 capture capacity, thermal stability, and capture/release cycles reversibility.Keywords: fish scales; tilapia; hydroxyapatite; calcium; CO 2 capture IntroductionMillions of tons of fish scales are discarded and wasted around the world. In Colombia, fish scales are considered worthless, unusable, and are often eliminated as waste. Consequently, the local fish industry generates large amounts of fish waste per year, of which tilapia scales have a considerable share. Ideas have been proposed on how to create value for fish scales and how to use this resource [1 -4]. The surface of fish scales is constituted by numerous high-value organic and inorganic components, such as hydroxyapatite

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“…Regarding Figure 12(d) and (e), it can be proved from these images that adding P3HB to n -TCP ceramic sca old and also the immersion time increase of sca olds in the polymer decrease the porosity of sca olds while maintaining a more interconnected porous structure which is bene cial for cells adhesion. Fabrication of pore interconnected porous structure is needed for the precise di usion of nutrients and gases, such as oxygen, and for the removal of metabolic wastes resulted from the activity of migrated cells that had, meanwhile, grown into the porous sca olds, thereby mimicking the cancellous bone structure [11,50]. Therefore, it is concluded that adding P3HB to n -TCP ceramic sca old decreases the pore size of sca olds, but it does not have harmful e ect on them, because the sca olds coated with a polymer have acceptable pore sizes for growing of bone cells, making them suitable candidates for bone replacement.…”

Section: Ft-ir Spectroscopymentioning

confidence: 99%

“…For example, there are signi cant drawbacks to the use of autologous bone, such as limited access and unsta-to act as a temporary physical framework allowing new tissues to grow and reconstruct the damaged ones [10]. In other words, tissue function restoration needs a template, a sca old, which will play the role of extracellular matrix in order to allow cells to attach, migrate, and duplicate tissue ingrowth until the new tissue is fully regenerated [11,12]. Bone tissue has a great potential for being restored to other body tissues [13].…”

Section: Introductionmentioning

confidence: 99%

“…Polymer replication methods enable the sca olds formation with uniform and adjustable porosity [29][30][31]. The method has been developed due to its interconnected pores that are similar to cancellous bone [11]. However, since CaPO 4 has a ceramic nature, they are brittle; therefore, biomedical applications of bare CaPO 4 sca olds for bone tissue reconstruction have been largely limited by their poor mechanical properties such as compression strength, compression module, and toughness [32].…”

Section: Introductionmentioning

confidence: 99%

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Evaluation of physical and mechanical properties of B-tri-calcium phosphate/poly-3-hydroxybutyrate nanocomposite scaffold for bone tissue engineering application

Shahi

Karbasi

2017

Scientia Iranica

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KEYWORDSNano--tricalcium phosphate ( -TCP); Poly-3-hydroxybutyrate (P3HB); Sca old; Tissue engineering.Abstract. One of the major challenges facing researchers of tissue engineering is the sca old design with desirable physical and mechanical properties for growth and proliferation of cells and tissue formation. In this paper, rstly, -tricalcium phosphate ( -TCP) nanopowders with particle size of 50-70 nm were synthesized using a simple sol-gel route with calcium nitrate and potassium dihydrogenphosphate as calcium and phosphorus precursors, respectively. Then, the porous ceramic sca old containing 40, 50, and 60 wt% of n -TCP was prepared by the polyurethane sponge replication method. The sca olds were coated with P3HB for 30 sec and 1 min in order to increase the sca old's mechanical properties. XRD, XRF, SEM, TEM, and FT-IR were used in order to study the phase and element structure, morphology, particle size, and determination of functional groups, respectively. Based on the results of compressive strength and porosimetry tests, the most appropriate type of sca old is 50 wt% of n -TCP immersed for 30 sec in P3HB with 75% porosity in 200-600 m, with a compressive strength of 1.09 MPa and a compressive modulus of 33 MPa, which can be utilized in bone tissue engineering.

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Fish scale derived hydroxyapatite scaffold for bone tissue engineering

Cited by 68 publications

References 28 publications

Naturally derived biomaterials for development of composite bone scaffold: A review

Naturally derived biomaterials for development of composite bone scaffold: A review

High temperature CO2 capture of hydroxyapatite extracted from tilapia scales

Evaluation of physical and mechanical properties of B-tri-calcium phosphate/poly-3-hydroxybutyrate nanocomposite scaffold for bone tissue engineering application

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