Sage Journals: Discover world-class research

Abstract

BACKGROUND:

Advances in bone tissue engineering offer novel options for the regeneration of bone tissue. In the current clinical treatment, the method of accelerating bone tissue regeneration rate by promoting early angiogenesis has been widely accepted.

OBJECTIVE:

This study aimed to develop a long-acting slow-release system using the pro-angiogenic drug tetramethylpyrazine (TMPZ) and pro-osteogenic drug icariin (ICA), which can be administered locally to achieve the sequential release of TMPZ and ICA for better clinically efficiency in the treatment of bone defects.

METHODS:

This study aimed to prepare microspheres with a core-shell structure using two polymers, poly lactic-co-glycolic acid and silk fibroin, by coaxial electrostatic spraying. Based on the therapeutic model for bone defects, the pro-angiogenic drug TMPZ and pro-osteogenic drug ICA were encapsulated in the shell and core layers of the microspheres, respectively. Subsequently, TMPZ and ICA were released sequentially to promote early angiogenesis and late osteogenesis, respectively, at the site of the bone defect. The optimal preparation parameters for preparing the drug-loaded microspheres were identified using the univariate controlled variable method. Additionally, microsphere morphology and core-shell structure, such as physical properties, drug-loading properties, in vitro degradation and drug release patterns, were characterised using scanning electron microscope and laser scanning confocal microscopy.

RESULTS:

The microspheres prepared in this study were well-defined and had a core-shell structure. The hydrophilicity of the drug-loaded microspheres changed compared to the no-load microspheres. Furthermore, in vitro results indicated that the drug-loaded microspheres with high encapsulation and loading efficiencies exhibited good biodegradability and cytocompatibility, slowly releasing the drug for up to three months.

CONCLUSION:

The development of the drug delivery system with a dual-step release mechanism has potential clinical applications and implications in the treatment of bone defects.

Keywords

Coaxial electrostatic spray core-shell structure microsphere sustained release

Get full access to this article

View all access options for this article.

References

Siddiqui

Kishori

Rao

Anjum

Hemanth

Das

, Electropsun polycaprolactone fibres in bone tissue engineering: a review, Molecular Biotechnology 63(5) (2021), 363–388.

Gibon

L.Y.

Nathan

and Goodman

S.B.

, Inflammation, ageing, and bone regeneration, Journal of Orthopaedic Translation 10 (2017), 28–35.

Velasco

M.A.

Narváez-Tovar

C.A.

and Garzón-Alvarado

D.A.

, Design, materials, and mechanobiology of biodegradable scaffolds for bone tissue engineering, BioMed Research International 2015 (2015), 729076.

Almubarak

Nethercott

Freeberg

Beaudon

Jha

Jackson

, Tissue engineering strategies for promoting vascularized bone regeneration, Bone 83 (2016), 197–209.

Roseti

Parisi

Petretta

Cavallo

Desando

Bartolotti

, Scaffolds for bone tissue engineering: state of the art and new perspectives, Materials Science and Engineering: C 78 (2017), 1246–1262.

Sharifi

Moghaddam

F.A.

Abedi

Maleki Dizaj

Ahmadian

Abdolahinia

E.D.

, Phytochemicals impact on osteogenic differentiation of mesenchymal stem cells, BioFactors (Oxford, England) 46(6) (2020), 874–893.

Buhrmann

Honarvar

Setayeshmehr

Karbasi

Shakibaei

and Valiani

, Herbal remedies as potential in cartilage tissue engineering: an overview of new therapeutic approaches and strategies, Molecules 25(13) (2020), 3075.

Chen

Cui

Luan

Zhou

and Han

, Icariin promotes the osteogenic action of BMP2 by activating the cAMP signaling pathway, Molecules 24(21) (2019), 3875.

Chen

Cai

Fang

Zhou

Lasanajak

, Puerariae Lobatae Radix with chuanxiong Rhizoma for treatment of cerebral ischemic stroke by remodeling gut microbiota to regulate the brain–gut barriers, The Journal of Nutritional Biochemistry 65 (2019), 101–114.

10.

Xia

Wang

Liu

and Gao

, Tetramethylpyrazine ameliorates high glucose-induced endothelial dysfunction by increasing mitochondrial biogenesis, PLoS One 9(2) (2014), e88243.

11.

Chen

Zhang

Gao

, A systematic review on the rhizome of Ligusticum chuanxiong Hort. (Chuanxiong), Food and Chemical Toxicology 119 (2018), 309–325.

12.

Qian

Xiong

Fang

and Wang

, Protective effect of tetramethylpyrazine on myocardial ischemia-reperfusion injury, Evid Based Complement Alternat Med 2014 (2014), 107501.

13.

Cai

Chen

Pan

Xia

Chen

Yang

, Inhibition of angiogenesis, fibrosis and thrombosis by tetramethylpyrazine: mechanisms contributing to the SDF-1/CXCR4 axis, PLoS One 9(2) (2014), e88176.

14.

Tian

Liu

Chen

Zhang

Shi

Zhang

, Tetramethylpyrazine promotes proliferation and differentiation of neural stem cells from rat brain in hypoxic condition via mitogen-activated protein kinases pathway in vitro , Neuroscience Letters 474(1) (2010), 26–31.

15.

Yang

Qian

Wang

Lin

Wang

, Tetramethylpyrazine protects against oxygen-glucose deprivation-induced brain microvascular endothelial cells injury via rho/rho-kinase signaling pathway, Cellular and Molecular Neurobiology 37(4) (2017), 619–633.

16.

Cao

and Lu

, Micro-CT as a tool to investigate the efficacy of tetramethylpyrazine in a rat spinal cord injury model, Spine 41(16) (2016), 1272–1278.

17.

Wang

Yang

Zhen

Zhang

and Peng

, The effect of icariin on bone metabolism and its potential clinical application, Osteoporosis International 29(3) (2018), 535–544.

18.

Cha

and Jsa

, Pharmacological effects of icariin, Advances in Pharmacology 87 (2020), 179–203.

19.

Yuan

Wan

Wei

Mao

Cai

, Dual-controlled release of Icariin/Mg2+ from biodegradable microspheres and their synergistic upregulation effect on bone regeneration, Advanced Healthcare Materials 9(11) (2020), 2000211.

20.

Gong

Chi

Liao

Xie

, Icariin-loaded electrospun PCL/gelatin nanofiber membrane as potential artificial periosteum, Colloids and Surfaces B: Biointerfaces 170 (2018), 201–209.

21.

Hossain

K.M.Z.

Patel

and Ahmed

, Development of microspheres for biomedical applications: a review, Prog Biomater 4(1) (2015), 1–19.

22.

Wei

J.X.

X.S.

and Ma

X.L.

, Biodegradable materials for bone defect repair, Military Medical Research 7(1) (2020), 1–25.

23.

Wang

Q.Y.

Chen

K.L.

Luo

J.B.

Zhou

Q.H.

and Lin

, Reduction/temperature/pH multi-stimuli responsive core cross-linked polypeptide hybrid micelles for triggered and intracellular drug release, Colloids and Surfaces B: Biointerfaces 170 (2018), 373–381.

24.

Cao

Wang

and Lou

, Dual drug release from core-shell nanoparticles with distinct release profiles, Journal of Pharmaceutical Sciences 103(10) (2014), 3205–3216.

25.

Wei

Wen

Bazybek

and Ma

, Recent research and development of local anesthetic-loaded microspheres, J Mater Chem B 8(30) (2020), 6322–6332.

26.

Miles

C.E.

Gwin

Zubris

K.A.V.

Gormley

A.J.

and Kohn

, Tyrosol derived poly (ester-arylate)s for sustained drug delivery from microparticles, ACS Biomaterials Science & Engineering 7(6) (2021), 2580–2591.

27.

Jin

Xia

Huang

Yuan

Zuo

, Recent advances in PLGA-based biomaterials for bone tissue regeneration, Acta Biomaterialia 127 (2021), 56–79.

28.

Patel

Jha

and Patel

, Potential application of PLGA microsphere for tissue engineering, Journal of Polymer Research 28(6) (2021), 1–17.

29.

Deng

Yang

Wang

Zhang

, 3D bio-printed biphasic scaffolds with dual modification of silk fibroin for the integrated repair of osteochondral defects, Biomaterials Science 9(14) (2021), 4891–4903.

30.

Wang

H.Y.

Zhang

Y.Q.

and Wei

Z.G.

, Characterization of undegraded and degraded silk fibroin and its significant impact on the properties of the resulting silk biomaterials, International Journal of Biological Macromolecules 176 (2021), 578–588.

31.

Mitra

Chadha

Muthuvijayan

and Doble

, Self-assembled inhalable immunomodulatory silk fibroin nanocarriers for enhanced drug loading and intracellular antibacterial activity, ACS Biomaterials Science & Engineering (2022).

32.

Wen

D.L.

Sun

D.H.

Huang

Wang

, Recent progress in silk fibroin-based flexible electronics, Microsystems & Nanoengineering 7(1) (2021), 35–35.

33.

Depeigne

and Zdraveva

, Electrospun biomaterials’ applications and processing, Journal of Biomimetics, Biomaterials and Biomedical Engineering 6290 (2021), 91–100.

34.

Kurakula

and Naveen

N.R.

, Electrospraying: a facile technology unfolding the chitosan based drug delivery and biomedical applications, European Polymer Journal 147 (2021), 110326.

35.

Lai

W.F.

Susha

A.S.

Rogach

A.L.

Wang

Huang

M.J.

W.J.

, Electrospray-mediated preparation of compositionally homogeneous core-shell hydrogel microspheres for sustained drug release, RSC Advances 7(70) (2017), 44482–44491.

36.

Meireles

A.B.

Corrêa

D.K.

da Silveira

J.V.

Millás

A.L.

Bittencourt

de Brito-Melo

G.E.

, Trends in polymeric electrospun fibers and their use as oral biomaterials, Experimental Biology and Medicine 243(8) (2018), 665–676.

37.

Yoon

Yang

H.S.

Lee

B.S.

and Yu

W.R.

, Recent progress in coaxial electrospinning: new parameters, various structures, and wide applications, Advanced Materials (Deerfield Beach, FL) 30(42) (2018), e1704765.

38.

Zong

Xia

Liang

Dai

Alsaedi

Hayat

, Designing function-oriented artificial nanomaterials and membranes via electrospinning and electrospraying techniques, Materials Science and Engineering: C 92 (2018), 1075–1091.

Preparation of drug-loaded microspheres with a core-shell structure using silk fibroin and poly lactic-co-glycolic acid and their application

Abstract

BACKGROUND:

OBJECTIVE:

METHODS:

RESULTS:

CONCLUSION:

Keywords

Get full access to this article

References