Drug Elution From High-Dose Antibiotic-Loaded Acrylic Cement: A Comparative, In Vitro Study

Gasparini, Giorgio; Gori, Marco De; Calonego, Giovanni; Bora, T. Della; Caroleo, Benedetto; Galasso, Olimpio

doi:10.3928/01477447-20141023-57

Cited by 42 publications

(32 citation statements)

References 34 publications

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“…Otherwise, desired concentrations cannot be achieved with poorly soluble antibiotics like cefepime or ampicillin. [8][9][10] Nonetheless, this method may work in the same way even if the molecule had high or low solubility. The effect might be more prominent in low solubility drugs.…”

Section: Discussionmentioning

confidence: 99%

Simple method for increasing drug elution from polymethylmethacrylate bone cement

Issın

Koçkara

2017

Eklem Hastalik Cerrahisi

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ÖZAmaç: Bu çalışmada sitrik asit ve sodyum bikarbonat karışımının polimetilmetakrilat kemik çimentosunda efervesan olarak kullanımının daha iyi ilaç elüsyonu açısından etkileri araştırıldı. Hastalar ve yöntemler: İçeriğinde 10'ar gram glikoz ve farklı miktarlarda efervesan (E) olan; parça sayıları (P), yüzey alanları, hacimleri ve poroziteleri farklı silindir çimento bloklar hazırlandı. Tüm blokların fiziksel özellikleri hesaplandı. Bloklar serum fizyolojik içeren kavanozlara konuldu ve sıvı içerisine salınan glikoz konsantrasyonları önceden belirlenen aralıklarda ölçüldü. Elüsyon hızı ve fiziksel özellikler arasındaki ilişkiler tanımlandı. Bulgular: Efervesanlı numunelerden elüsyon oranları anlamlı derecede daha yüksekti. Kırk beşinci günün sonunda E 0 P 1 glikoz içeriğinin ortalama %21'ini saldı. Bu değer E 0 P 2 , E 0 P 4 , E 2 P 1 ve E 4 P 1 için sırasıyla %38, %61, %82 ve %88 idi. Su absorbsiyon oranları, yüzey alanları, porozite ve glikoz elüsyonu oranları arasında güçlü korelasyonlar saptandı (r= 0,942, p<0,01; r= 0,894, p<0,05; r= 0,918, p<0,05). Sonuç: Sodyum bikarbonat ve sitrik asidin efervesan olarak kemik çimentosu içinde kullanılması, daha iyi antibiyotik elüsyonu için tatmin edici porozite oluşumunu sağlamaktadır. Yekpare bir spacer ve daha iyi lokal antibiyotik elüsyonu gereken durumlarda bu yöntem işe yarayabilir.Anahtar sözcükler: Antibiyotik, kemik çimentosu; çimento spacer; elüsyon; polimetilmetakrilat. ABSTRACT Objectives:This study aims to investigate the effects of the use of citric acid and sodium bicarbonate mixture as an effervescent in polymethylmethacrylate bone cement in terms of better drug elution. Patients and methods: Multiple cylinder cement blocks each containing 10 g of glucose and different amounts of effervescent (E), with different numbers of pieces (P), surface areas, volumes, and porosities were prepared. Physical properties of all blocks were calculated. Blocks were placed in jars containing saline solutions and the released glucose concentrations were measured at predefined intervals. Correlations between elution rate and physical properties were defined. Results: Elution rates were significantly higher in samples with effervescent. At the end of 45 th day, E 0 P 1 released mean 21% of its glucose content. This value was 38%, 61%, 82% and 88% for E 0 P 2 , E 0 P 4 , E 2 P 1 and E 4 P 1 , respectively. Strong correlations were detected between water absorption ratio, surface areas, porosity and glucose elution rates (r= 0.942, p<0.01; r= 0.894, p<0.05; r= 0.918, p<0.05). Conclusion: Using sodium bicarbonate and citric acid as effervescent in bone cement provides satisfactory porosity development for better antibiotic elution. This method may be useful when a monolithic spacer and better local antibiotic elution are required.

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Section: Discussionmentioning

confidence: 99%

Simple method for increasing drug elution from polymethylmethacrylate bone cement

Issın

Koçkara

2017

Eklem Hastalik Cerrahisi

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“…Furthermore, when higher quantities of antibiotics (2–4 g per 40 g of PMMA [42]) are placed within the articular space in the form of a bone cement spacer to treat PJI, retrieval studies have demonstrated that offending bacteria remain alive within the surrounding tissues [43]. More recent investigations have revealed the limitations of using PMMA as a method of antibiotic-delivery: antibiotics rapidly elute within the first 24 h, but logarithmically decline over a matter of days [44]; antibiotic release is limited to the outer 100 μm layer of the PMMA [45]; and that prolonged sub-therapeutic intra-articular concentrations of antibiotic can undesirably lead to the development of drug-resistant bacteria [24]. …”

Section: Contemporary Treatment Of Pji: Limited Successmentioning

confidence: 99%

“…In response to the above limitations, investigators have responded by changing the mixing process of PMMA to increase porosity and improve elution profiles [44], using binding agents to increase elution [46] and using newer antibiotics with longer half-lives in an effort to prolong their intraarticular effects [47]. More recently, good PJI treatment success rates have been reported by introducing a percutaneous catheter at the time of revision surgery and regularly infusing antibiotics into the joint space for several weeks [48].…”

Section: Contemporary Treatment Of Pji: Limited Successmentioning

confidence: 99%

Current Options and Emerging Biomaterials for Periprosthetic Joint Infection

et al. 2018

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Recent advancements in local antibiotic delivery platforms for preventing and treating PJI include titanium nanotube arrays, synthetic polymers, resorbable hydrogels, and cyclodextrin-based drug delivery options. In particular, cyclodextrins have facilitated great advancements in other clinical disorders and have demonstrated early promise as a future option in the arena of PJI. Novel treatment modalities for PJI optimize the implant surfaces to prevent bacterial biofilm formation or provide prolonged intra-articular antibiotic dosing to eradicate bacteria.

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“…Linezolid is generally a bacteriostatic agent with a spectrum of activity comparable with that of daptomycin. From a practical standpoint, 22,49 0.5 g 1 g Y 1.25% w/w maximum studied in vitro Fluconazole 16,52 NR 2 g N 8% w/w maximum studied in vitro Gentamicin 21,22,24,37,44 0.5-1 g 0.25-4.8 g N Imipenem-cilastatin 41,44 NR NR Y 10% w/w maximum studied in vitro Linezolid 53,54 NR NR N 15% w/w maximum studied in vitro Meropenem 17, 55 5 g NR Y 20% w/w maximum studied in vitro Micafungin 16 NR NR Y 4% w/w maximum studied in vitro Moxifloxacin 17 NR NR N 20% w/w maximum studied in vitro Piperacillin 38,44 NR 8 g Y 2.5% w/w maximum studied in vitro Piperacillin-tazobactam 22 NR 4.5 g Y Rifampin 17 NR NR Y 20% w/w maximum studied in vitro Teicoplanin 35,41,44,56 NR 3.6-10 g e Y f 10% w/w maximum studied in vitro Tigecycline 35,57 NR NR Y 10% w/w maximum studied in vitro Tobramycin 22,42,44 0.5-1. linezolid incorporates into PMMA and appears to withstand the temperatures generated during polymerization. 53,54 Linezolid is commercially available as a solution for injection, a filmcoated tablet, and flavored granules for oral suspension.…”

Section: Oxazolidinonesmentioning

confidence: 99%

Trowels and Tribulations: Review of Antimicrobial‐Impregnated Bone Cements in Prosthetic Joint Surgery

2017

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Antimicrobial-impregnated bone cement (AIBC) is a staple of contemporary orthopedic surgery and has been used to either treat or prevent prosthetic joint infection. Applied intraoperatively during primary arthroplasty or prosthetic joint exchange, this drug-delivery vehicle has become a popular means of maximizing drug concentrations within a joint space while minimizing systemic exposure. Antimicrobial characteristics conducive to cement loading include availability of a crystalline powder formulation, molecular characteristics, minimal impact on cement integrity, and other variables promoting drug elution. Antimicrobials most commonly incorporated into cements are vancomycin and aminoglycosides, usually in combination due to synergistic antibacterial activity and enhanced cement elution. Other classes include the β-lactams, lipopeptides, oxazolidinones, and antifungals. With the exception of several commercially available AIBCs, most products are compounded extemporaneously without a formal safety or efficacy assessment. Few randomized controlled trials have been conducted to assess the benefit or optimal use of these cement preparations, and variable methodology renders cross-study comparison challenging. Given the lack of standardization and multidisciplinary oversight often seen with practical AIBC use, additional data are needed. This review presents information intended to guide AIBC preparation, selection, dosing, and safe use. In addition, opportunities for best practice development, antimicrobial stewardship, and future research are discussed.

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Drug Elution From High-Dose Antibiotic-Loaded Acrylic Cement: A Comparative, In Vitro Study

Cited by 42 publications

References 34 publications

Simple method for increasing drug elution from polymethylmethacrylate bone cement

Simple method for increasing drug elution from polymethylmethacrylate bone cement

Current Options and Emerging Biomaterials for Periprosthetic Joint Infection

Trowels and Tribulations: Review of Antimicrobial‐Impregnated Bone Cements in Prosthetic Joint Surgery

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