Systemic administration of alendronate is associated with various adverse reactions in clinical settings. To mitigate these side effects, poloxamer 407 (P-407) modified with cellulose was chosen to encapsulate alendronate. This drug-loaded system was then incorporated into a collagen/β-tricalcium phosphate (β-TCP) scaffold to create a localized drug delivery system. Nuclear magnetic resonance spectrum and rheological studies revealed hydrogen bonding between P-407 and cellulose as well as a competitive interaction with water that contributed to the delayed release of alendronate (ALN). Analysis of the degradation kinetics of P-407 and release kinetics of ALN indicated zero-order kinetics for the former and Fickian or quasi-Fickian diffusion for the latter. The addition of cellulose, particularly carboxymethyl cellulose (CMC), inhibited the degradation of P-407 and prolonged the release of ALN. The scaffold’s structure increased the contact area of P-407 with the PBS buffer, thereby, influencing the release rate of ALN. Finally, biocompatibility testing demonstrated that the drug delivery system exhibited favorable cytocompatibility and hemocompatibility. Collectively, these findings suggest that the drug delivery system holds promise for implantation and bone healing applications.
ReidIRBillingtonEO. Drug therapy for osteoporosis in older adults. Lancet2022; 399: 1080–1092.
2.
SongSGuoYYangY, et al.Advances in pathogenesis and therapeutic strategies for osteoporosis. Pharmacol Therapeut2022; 237: 108168.
3.
RussellRGGWattsNBEbetinoFH, et al.Mechanisms of action of bisphosphonates: similarities and differences and their potential influence on clinical efficacy. Osteoporos Int2008; 19: 733–759.
4.
LeeESTsaiMCLeeJX, et al.Bisphosphonates and their connection to dental procedures: exploring bisphosphonate-related osteonecrosis of the jaws. Cancers2023; 15: 5366.
5.
ChinKYEkeukuSOTriasA. The role of geranylgeraniol in managing bisphosphonate-related osteonecrosis of the jaw. Front Pharmacol2022; 13: 878556.
6.
DasTVenkateshMPKumarTMP, et al.SLN based alendronate in situ gel as an implantable drug delivery system - a full factorial design approach. J Drug Deliv Sci Technol2020; 55: 101415.
7.
MurphyCMSchindelerAGleesonJP, et al.A collagen-hydroxyapatite scaffold allows for binding and co-delivery of recombinant bone morphogenetic proteins and bisphosphonates. Acta Biomater2014; 10: 2250–2258.
8.
ZhangJXBaiHTBaiM, et al.Bisphosphonate-incorporated coatings for orthopedic implants functionalization. Materials Today Bio2023; 22: 100737.
9.
SandomierskiMZielińskaMBuchwaldT, et al.Controlled release of the drug for osteoporosis from the surface of titanium implants coated with calcium titanate. J Biomed Mater Res B Appl Biomater2022; 110: 431–437.
ShiLChenJRTianY, et al.Hydroxyapatite gradient on poly (vinyl alcohol) hydrogels surface to mimic calcified cartilage zone for cartilage repair. J Biomater Appl2022; 36: 1579–1587.
12.
KornPKramerIFSchlottigF, et al.Systemic sclerostin antibody treatment increases osseointegration and biomechanical competence of zoledronic-acid-coated dental implants in a rat osteoporosis model. Eur Cell Mater2019; 37: 333–346.
13.
BrambillaELocarnoSGalloS, et al.Poloxamer-based hydrogel as drug delivery system: how polymeric excipients influence the chemical-physical properties. Polymers2022; 14: 3624.
14.
MfoafoKKwonYOmidiY, et al.Contemporary applications of thermogelling PEO-PPO-PEO triblock copolymers. J Drug Deliv Sci Technol2022; 70: 103182.
15.
OsouliMAbdollahizadEAlaviS, et al.Biocompatible phospholipid-based mixed micelles for posaconazole ocular delivery: development, characterization, and in-vitro antifungal activity. J Biomater Appl2023; 37: 969–978.
16.
ZhengJZhangYWZhangSX. Sustained release of azithromycin from lipid liquid-crystalline nanoparticles laden in situ gel for the treatment of periodontitis: in vitro and efficacy study. J Biomater Appl2022; 37: 482–492.
17.
GiulianoEPaolinoDFrestaM, et al.Mucosal applications of poloxamer 407-based hydrogels: an overview. Pharmaceutics2018; 10: 159.
18.
KhanSAkhtarNMinhasMU. Fabrication, rheological analysis, and in vitro characterization of in situ chemically cross-linkable thermogels as controlled and prolonged drug depot for localized and systemic delivery. Polym Adv Technol2019; 30: 755–771.
19.
García-CouceJSchomannTChungCK, et al.Thermosensitive injectable hydrogels for intra-articular delivery of etanercept for the treatment of osteoarthritis. Gels2022; 8: 488.
20.
MooreTCroySMallapragadaS, et al.Experimental investigation and mathematical modeling of Pluronic (R) F127 gel dissolution: drug release in stirred systems. J Contr Release2000; 67: 191–202.
21.
HeXTLiWLiuSY, et al.Fabrication of high-strength, flexible, porous collagen-based scaffolds to promote tissue regeneration. Materials Today Bio2022; 16: 100376.
22.
CarrBPChenZChungJHY, et al.Collagen alignment via electro-compaction for biofabrication applications: a review. Polymers2022; 14: 4270.
23.
LiuTLiBLChenG, et al.Nano tantalum-coated 3D printed porous polylactic acid/beta-tricalcium phosphate scaffolds with enhanced biological properties for guided bone regeneration. Int J Biol Macromol2022; 221: 371–380.
24.
ZhangFQYangJZZuoYB, et al.Digital light processing of β-tricalcium phosphate bioceramic scaffolds with controllable porous structures for patient specific craniomaxillofacial bone reconstruction. Mater Des2022; 216: 110558.
25.
DumortierGGrossiordJLAgnelyF, et al.A review of poloxamer 407 pharmaceutical and pharmacological characteristics. Pharmaceut Res2006; 23: 2709–2728.
26.
CuiYTZhuTTLiD, et al.Bisphosphonate-functionalized scaffolds for enhanced bone regeneration. Adv Healthcare Mater2019; 8: e1901073.
27.
BaheiraeiNNouraniMRMortazaviSMJ, et al.Development of a bioactive porous collagen/β-tricalcium phosphate bone graft assisting rapid vascularization for bone tissue engineering applications. J Biomed Mater Res2018; 106: 73–85.
28.
OhSHParkIKKimJM, et al.In vitro and in vivo characteristics of PCL scaffolds with pore size gradient fabricated by a centrifugation method. Biomaterials2007; 28: 1664–1671.
29.
KuljaninJJankovicINedeljkovicJ, et al.Spectrophotometric determination of alendronate in pharmaceutical formulations via complex formation with Fe(III) ions. J Pharmaceut Biomed Anal2002; 28: 1215–1220.
30.
RitgerPLPeppasNA. A simple equation for description of solute release II. Fickian and anomalous release from swellable devices. J Contr Release1987; 5: 37–42.
SinglaPChabbaSMahajanRK. A systematic physicochemical investigation on solubilization and in vitro release of poorly water soluble oxcarbazepine drug in pluronic micelles. Colloids Surf A Physicochem Eng Asp2016; 504: 479–488.
33.
YangHLLuHTMiaoYY, et al.Non-swelling, super-tough, self-healing, and multi-responsive hydrogels based on micellar crosslinking for smart switch and shape memory. Chem Eng J2022; 450: 138346.
34.
ShinH-CAlaniAWGRaoDA, et al.Multi-drug loaded polymeric micelles for simultaneous delivery of poorly soluble anticancer drugs. J Contr Release2009; 140: 294–300.
35.
DewanMAdhikariADuttaK, et al.Impact of oly (vinyl alcohol) on the thermogelation property and drug release profile of ophthalmic formulations based on poloxamer 407. ChemistrySelect2023; 8: e20220352.
36.
García-CouceJTomásMFuentesG, et al.Chitosan/Pluronic F127 thermosensitive hydrogel as an injectable dexamethasone delivery carrier. Gels2022; 8: 44.
SalvatoreLGalloNAielloD, et al.An insight on type I collagen from horse tendon for the manufacture of implantable devices. Int J Biol Macromol2020; 154: 291–306.
39.
InoueYHisaISeinoS, et al.Alendronate induces mineralization in mouse osteoblastic MC3T3-E1 cells: regulation of mineralization-related genes. Exp Clin Endocrinol Diabetes2010; 118: 719–723.
40.
GangoitiMVCortizoAMArnolV, et al.Opposing effects of bisphosphonates and advanced glycation end-products on osteoblastic cells. Eur J Pharmacol2008; 600: 140–147.
41.
AhnGYKimSYunTH, et al.Enhanced osteogenic differentiation of alendronate-conjugated nanodiamonds for potential osteoporosis treatment. Biomater Res2021; 25: 28.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
