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Abstract

Synthetic thermoplastic polymers are a widespread choice as material candidates for scaffolds for tissue engineering (TE), thanks to their ease of processing and tunable properties with respect to biological polymers. These features made them largely employed in melt-extrusion-based additive manufacturing, with particular application in hard-TE. In this field, high molecular weight (M_w) polymers ensuring entanglement network strength are often favorable candidates as scaffold materials because of their enhanced mechanical properties compared with lower M_w grades. However, this is accompanied by high viscosities once processed in molten conditions, which requires driving forces not always accessible technically or compatible with often chemically nonstabilized biomedical grades. When possible, this is circumvented by increasing the operating temperature, which often results in polymer chain scission and consequent degradation of properties. In addition, synthetic polymers are mostly considered bioinert compared with biological materials, and additional processing steps are often required to make them favorable for tissue regeneration. In this study, we report the plasticization of a common thermoplastic polymer with cholecalciferol, the metabolically inactive form of vitamin D3 (VD3). Plasticization of the polymer allowed us to reduce its melt viscosity, and therefore the energy requirements (mechanical [torque] and heat [temperature]) for extrusion, limiting ultimately polymer degradation. In addition, we evaluated the effect of cholecalciferol, which is more easily available than its active counterpart, on the osteogenic differentiation of human mesenchymal stromal cells (hMSCs). Results indicated that cholecalciferol supported osteogenic differentiation more than the osteogenic culture medium, suggesting that hMSCs possess the enzymatic toolbox for VD3 metabolism.

Impact statement

Limitations in mechanical and biological performances of scaffolds manufactured through melt deposition may result from material thermal degradation during processing and inherent bioinertness of synthetic polymers. Current approaches involve the incorporation of chemical additives to reduce the extent of thermal degradation, which are often nonbiocompatible or may lead to uncontrolled modifications to the polymer structure. Lack of polymer bioactivity is tackled by postfunctionalization methods that often involve extra processes extending scaffold production time. Therefore, new methods to improve scaffolds performances should consider preserving the integrity of the molecular structure and improving biological responsiveness of the material while keeping the process as straightforward as possible.

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References

Van Blitterswijk

C.A.

, and De Boer

, eds. Tissue Engineering: Second Edition [Internet]. Cambridge, United States: Elsevier, 2014. Available from: https://linkinghub.elsevier.com/retrieve/pii/B9780124201453000146

Mota

, Puppi

, Chiellini

, and Chiellini

Additive manufacturing techniques for the production of tissue engineering constructs. J Tissue Eng Regen Med, 9, 174, 2015.

Middleton

J.C.

, and Tipton

A.J.

Synthetic biodegradable polymers as orthopedic devices. Biomaterials, 21, 2335, 2000.

Hutmacher

D.W.

Scaffold design and fabrication technologies for engineering tissues—State of the art and future perspectives. J Biomater Sci Polym Ed, 12, 107, 2001.

Hoying

J.B.

, and Williams

S.K.

Essentials of 3D Biofabrication and Translation. In: Atala, A., and Yoo, J.J., eds. Winston-Salem, NC: Elsevier, 2015. Available from: http://www.sciencedirect.com/science/article/pii/B9780128009727000190

Osswald

, and Rudolph

Polymer Rheology [Internet]. München: Carl Hanser Verlag GmbH & Co. KG, 2014. Available from: http://www.hanser-elibrary.com/doi/book/10.3139/9781569905234

Camarero-Espinosa

, Calore

A.R.

, Wilbers

, Harings

, and Moroni

Additive manufacturing of an elastic poly(ester)urethane for cartilage tissue engineering. Acta Biomater, 102, 192, 2020.

Camarero-Espinosa

, Tomasina

, Calore

A.R.

, and Moroni

Additive manufactured, highly resilient, elastic, and biodegradable poly(ester)urethane scaffolds with chondroinductive properties for cartilage tissue engineering. Mater Today Bio, 6, 100051, 2020.

Calore

A.R.

, Sinha

, Harings

, Bernaerts

K.V

, Mota

, and Moroni

Chapter 7: Thermoplastics for tissue engineering. In: Rainer, A., and Moroni, L., eds. Computer Tissue Engineering, 2021, pp. 75–99.

10.

Ragaert

, Dekeyser

, Cardon

, and Degrieck

Quantification of thermal material degradation during the processing of biomedical thermoplastics. J Appl Polym Sci, 120, 2872, 2011.

11.

Poh

P.S.P.

, Chhaya

M.P.

, Wunner

F.M.

, et al. Polylactides in additive biomanufacturing. Adv Drug Deliv Rev, 107, 228, 2016.

12.

Choong

G.Y.H.

, and De Focatiis

D.S.A.

A method for the determination and correction of the effect of thermal degradation on the viscoelastic properties of degradable polymers. Polym Degrad Stab, 130, 182, 2016.

13.

Lehermeier

H.J.

, and Dorgan

J.R.

Melt rheology of poly(lactic acid): consequences of blending chain architectures. Polym Eng Sci, 41, 2172, 2001.

14.

Villalobos

, Awojulu

, Greeley

, Turco

, and Deeter

Oligomeric chain extenders for economic reprocessing and recycling of condensation plastics. Energy, 31, 3227, 2006.

15.

Yang

L.X.

, Chen

X.S.

, and Jing

X.B.

Stabilization of poly(lactic acid) by polycarbodiimide. Polym Degrad Stab, 93, 1923, 2008.

16.

Tachibana

, Maeda

, Ito

, Maeda

, and Kunioka

Biobased myo-inositol as nucleator and stabilizer for poly(lactic acid). Polym Degrad Stab, 95, 1321, 2010.

17.

Parthasarathy

L.K.

, Seelan

R.S.

, Tobias

, Casanova

M.F.

, and Parthasarathy

R.N.

Mammalian inositol 3-phosphate synthase: its role in the biosynthesis of brain inositol and its clinical use as a psychoactive agent. In: Majumder

A.L.

, Biswas

B.B.

, eds. Biology of Inositols and Phosphoinositides. Subcellular Biochemistry, vol 39. Boston, United States: Springer, pp. 293–314, 2006.

18.

Ngo

T.D.

, Kashani

, Imbalzano

, Nguyen

K.T.Q.

, and Hui

Additive manufacturing (3D printing): a review of materials, methods, applications and challenges. Compos Part B Eng, 143, 172, 2018.

19.

Norman

Dowling. Mechanical Behavior of Materials. Boston, United. States: Prentice Hall, 2013.

20.

Harper

C.A.

Modern Plastics Handbook. New York, United. States: McGraw-Hill Professional, 2000.

21.

Martin

, and Avérous

Poly(lactic acid): plasticization and properties of biodegradable multiphase systems. Polymer, 42, 6209, 2001.

22.

, Mao

, and Gao

Surface modification and property analysis of biomedical polymers used for tissue engineering. Colloids Surf B Biointerfaces, 60, 137, 2007.

23.

Cámara-Torres

, Sinha

, Scopece

, et al. Tuning cell behavior on 3D scaffolds fabricated by atmospheric plasma-assisted additive manufacturing. ACS Appl Mater Interfaces, 13, 3631-3644, 2021.

24.

Zhu

, Leong

M.F.

, Ong

W.F.

, Chan-Park

M.B.

, and Chian

K.S.

Esophageal epithelium regeneration on fibronectin grafted poly(l-lactide-co-caprolactone) (PLLC) nanofiber scaffold. Biomaterials, 28, 861, 2007.

25.

Marchioli

, Luca

Di, de Koning, E., et al. Hybrid polycaprolactone/alginate scaffolds functionalized with VEGF to promote de novo vessel formation for the transplantation of islets of langerhans. Adv Healthc Mater, 5, 1606, 2016.

26.

Place

E.S.

, George

J.H.

, Williams

C.K.

, and Stevens

M.M.

Synthetic polymer scaffolds for tissue engineering. Chem Soc Rev, 38, 1139, 2009.

27.

Yoon

J.J.

, Kim

J.H.

, and Park

Dexamethasone-releasing biodegradable polymer scaffolds fabricated by a gas-foaming/salt-leaching method. Biomaterials, 24, 2323, 2003.

28.

Bhutto

M.A.

, Wu

, Sun

, EI-Hamshary

, Al-Deyab

S.S.

, and Mo

Fabrication and characterization of vitamin B5 loaded poly (l-lactide-co-caprolactone)/silk fiber aligned electrospun nanofibers for schwann cell proliferation. Colloids Surf B Biointerfaces, 144, 108, 2016.

29.

Damanik

F.F.R.

, van Blitterswijk

, Rotmans

, and Moroni

Enhancement of synthesis of extracellular matrix proteins on retinoic acid loaded electrospun scaffolds. J Mater Chem B, 6, 6468, 2018.

30.

Yeong

W.Y.

, Chua

C.K.

, Leong

K.F.

, and Chandrasekaran

Rapid prototyping in tissue engineering: challenges and potential. Trends Biotechnol, 22, 643, 2004.

31.

Anderson

P.H.

, and Atkins

G.J.

The skeleton as an intracrine organ for vitamin D metabolism. Mol Aspects Med, 29, 397, 2008.

32.

Hou

Y.-C.

, Lu

C.-L.

, Zheng

C.-M.

, et al. The role of vitamin D in modulating mesenchymal stem cells and endothelial progenitor cells for vascular calcification. Int J Mol Sci, 21, 2466, 2020.

33.

Zhou

, LeBoff

M.S.

, and Glowacki

Vitamin D metabolism and action in human bone marrow stromal cells. Endocrinology, 151, 14, 2010.

34.

Geng

, Zhou

, Bi

, and Glowacki

Vitamin D metabolism in human bone marrow stromal (mesenchymal stem) cells. Metabolism, 62, 768, 2013.

35.

Kang

D.J.

, Lee

H.S.

, Park

J.T.

, Bang

J.S.

, Hong

S.K.

, and Kim

T.Y.

Optimization of culture conditions for the bioconversion of vitamin D3 to 1α,25-dihydroxyvitamin D3 using Pseudonocardia autotrophica ID9302. Biotechnol Bioprocess Eng, 11, 408, 2006.

36.

Feldman

, Pike

J.W.

, and Adams

J.S.

, eds. Vitamin D [Internet]. Elsevier, 2011. Available from: https://www.emerald.com/insight/content/doi/10.1108/nfs.2011.01741faa.017/full/html

37.

Meng

, Bertucci

, Gao

, et al. Fibroblast growth factor 23 counters vitamin D metabolism and action in human mesenchymal stem cells. J Steroid Biochem Mol Biol, 199, 105587, 2020.

38.

Sinha

, Sanchez

, Camara-Torres

, et al. Additive manufactured scaffolds for bone tissue engineering: physical characterization of thermoplastic composites with functional fillers. ACS Appl Polym Mater, 3, 3788, 2021.

39.

Macosko

Rheology: Principles, Measurements and Applications. New York, United. States: Wiley-VCH, 1994.

40.

Cámara-Torres

, Sinha

, Mota

, and Moroni

Improving cell distribution on 3D additive manufactured scaffolds through engineered seeding media density and viscosity. Acta Biomater, 101, 183, 2020.

41.

Gregory

C.A.

, Gunn

W.G.

, Peister

, and Prockop

D.J.

An Alizarin red-based assay of mineralization by adherent cells in culture: comparison with cetylpyridinium chloride extraction. Anal Biochem, 329, 77, 2004.

42.

Morrison

F.A.

Understanding Rheology, New York: Oxford University Press, 2001.

43.

Kang

E.Y.

, Lih

, Kim

I.H.

, Joung

Y.K.

, and Han

D.K.

Effects of poly(L-lactide-ɛ-caprolactone) and magnesium hydroxide additives on physico-mechanical properties and degradation of poly(L-lactic acid). Biomater Res, 20, 7, 2016.

44.

Speranza

, De Meo

, and Pantani

Thermal and hydrolytic degradation kinetics of PLA in the molten state. Polym Degrad Stab, 100, 37, 2014.

45.

Rauwendaal

Polymer Extrusion [Internet]. München: Carl Hanser Verlag GmbH & Co. KG, 2014. Available from: http://www.hanser-elibrary.com/doi/book/10.3139/9781569905395

46.

Meyers

M.A.

, and Chawla

K.K.

Mechanical Behavior of Materials [Internet]. Cambridge: Cambridge University Press, 2008. Available from: http://ebooks.cambridge.org/ref/id/CBO9780511810947

47.

Mallouk

R.S.

, and McKelvey

J.M.

Power requirements of melt extruders. Ind Eng Chem, 45, 987, 1953.

48.

Coppola

, Grizzuti

, and Maffettone

P.L.

Microrheological modeling of flow-induced crystallization. Macromolecules, 34, 5030, 2001.

49.

McIlroy

Claire

, and Peter

. Olmsted. Deformation of an amorphous polymer during the fused-filament-fabrication method for additive manufacturing. J Rheol, 61.2, 379, 2017.

50.

Pelc

, and Marshall

D.H.

Thermal transformation of cholecalciferol between 100–170°C. Steroids, 31, 23, 1978.

51.

Jakobsen

, and Knuthsen

Stability of vitamin D in foodstuffs during cooking. Food Chem, 148, 170, 2014.

52.

Carley

J.F.

, and Strub

R.A.

Application of theory to design of screw extruders. Ind Eng Chem, 45, 978, 1953.

53.

Van Krevelen

D.W.

, and Te Nijenhuis

Properties of Polymers, 2009. Available from: https://www.elsevier.com/books/properties-of-polymers/van-krevelen/978-0-08-054819-7

54.

Ward

I.M.

, and Sweeney

An Introduction to the Mechanical Properties of Solid Polymers, Hoboken, United. States: John Wiley & Sons, 2004.

55.

Utracki

L.A.

, and Wilkie

C.A.

, eds. Polymer Blends Handbook [Internet]. Dordrecht, Netherlands: Springer, 2014. Available from: http://link.springer.com/10.1007/978-94-007-6064-6

56.

Tham

C.Y.

, Hamid

Z.A.A.

, Ahmad

Z.A.

, and Ismail

Surface engineered poly(lactic acid) (PLA) microspheres by chemical treatment for drug delivery system. Key Eng Mater, 594–595, 214, 2013.

57.

Park

, Yuan

, Choi

S.-O.

, and Kim

Doxorubicin release controlled by induced phase separation and use of a co-solvent. Materials (Basel), 11, 681, 2018.

58.

Almarri

, Haq

, Alanazi

F.K.

, et al. Solubility and thermodynamic function of vitamin D3 in different mono solvents. J Mol Liq, 229, 477, 2017.

59.

Vlachopoulos

, and Strutt

The role of rheology in polymer extrusion. Extrusion Minitec and Conference: From Basics to Recent Developments, Milan, Italy, November 2003, pp. 20–21.

60.

Ignjatović

, Uskoković

, Ajduković

, and Uskoković

Multifunctional hydroxyapatite and poly(d,l-lactide-co-glycolide) nanoparticles for the local delivery of cholecalciferol. Mater Sci Eng C, 33, 943, 2013.

61.

Fayyazbakhsh

, Solati-Hashjin

, Keshtkar

, Shokrgozar

M.A.

, Dehghan

M.M.

, and Larijani

Release behavior and signaling effect of vitamin D3 in layered double hydroxides-hydroxyapatite/gelatin bone tissue engineering scaffold: an in vitro evaluation. Colloids Surf B Biointerfaces, 158, 697, 2017.

62.

Fromigué

, Marie

P.J.

, and Lomri

Differential effects of transforming growth factor β2, dexamethasone and 1,25-Dihydroxyvitamin D on human bone marrow stromal cells. Cytokine, 9, 613, 1997.

63.

Lips

Vitamin D physiology. Prog Biophys Mol Biol, 92, 4, 2006.

64.

Calore

A.R.

, Srinivas

, Anand

, et al. Shaping and properties of thermoplastic scaffolds in tissue regeneration: the effect of thermal history on polymer crystallization, surface characteristics and cell fate. J Mater Res, 36, 3914, 2021.

65.

Deb

, Reeves

A.A.

, and Lafortune

Simulation of physicochemical and pharmacokinetic properties of vitamin D3 and its natural derivatives. Pharmaceuticals, 13, 160, 2020.

66.

Geng

, Zhou

, and Glowacki

Effects of 25-hydroxyvitamin D3 on proliferation and osteoblast differentiation of human marrow stromal cells require CYP27B1/1α-hydroxylase. J Bone Miner Res, 26, 1145, 2011.

67.

Lian

J.B.

, and Stein

G.S.

Concepts of osteoblast growth and differentiation: basis for modulation of bone cell development and tissue formation. Crit Rev Oral Biol Med, 3, 269, 1992.

68.

Aubin

J.E.

Regulation of osteoblast formation and function. Rev Endocr Metab Disord, 2, 81, 2001.

69.

Freeman

F.E.

, Stevens

H.Y.

, Owens

, Guldberg

R.E.

, and McNamara

L.M.

Osteogenic differentiation of mesenchymal stem cells by mimicking the cellular niche of the endochondral template. Tissue Eng Part A, 22, 1176, 2016.

70.

Costa

P.F.

, Puga

A.M.

, Díaz-Gomez

, Concheiro

, Busch

D.H.

, and Alvarez-Lorenzo

Additive manufacturing of scaffolds with dexamethasone controlled release for enhanced bone regeneration. Int J Pharm, 496, 541, 2015.

71.

Wubneh

, Tsekoura

E.K.

, Ayranci

, and Uludağ

Current state of fabrication technologies and materials for bone tissue engineering. Acta Biomater, 80, 1, 2018.

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Cholecalciferol as Bioactive Plasticizer of High Molecular Weight Poly(D,L-Lactic Acid) Scaffolds for Bone Regeneration

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