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Drug delivery systems applications

Various Drug Delivery Systems Application of Biodegradable Polymers.1263... [Pg.1255]

VARIOUS DRUG DELIVERY SYSTEMS APPLICATION OF BIODEGRADABLE POLYMERS... [Pg.1263]

Abstract Polysaccharides based nanomaterials have diverse applications in biomedical research. This chapter covers one of the major achievements in modification of polysaccharides using microwave irradiation and cationization methods. Additionally chapter focused on mucoadhesive polysaccharides and its recent advancement in nano drug delivery system. Applications such as gene transfection, bone regeneration and vaccine delivery are also separately discussed. [Pg.171]

D. Jain, and D. Bar-Shalom, Alginate drug delivery systems Application in context of pharmaceutical and biomedical research. Drug Dev. Ind. Pharm., 1-9,2014. [Pg.512]

P. Pawan, P. Mayur, S. Aswin. Role of natural polymers in sustained release drug delivery system Applications and recent approaches. IntRes J Pharm. 2 (9) 6-11, 2011. [Pg.498]

Onishi, FI., Nagai, T., Machida, Y. Applications of chitin, chitosan, and their derivatives to drug carriers for microparticulated or conjugated drug delivery systems. Application of chitin and chitosan. 1997, 407-409. [Pg.328]

Xylans from beech wood, corncobs, and the alkaline steeping liquor of the viscose process have been shown to be applicable as pharmaceutical auxiliaries [3]. Micro- and nanoparticles were prepared by a coacervation method from xylan isolated from corncobs [150]. The process is based on neutralization of an alkaline solution in the presence of surfactant, which was shown to influence both the particle size and morphology. They are aimed at applications in drug delivery systems. [Pg.22]

Pitt, C. G., Marks, T. A., and Schindler, A., Biodegradable drug delivery systems based on aliphatic polyesters application to contraceptives and narcotic antagonists, in Controlled Release of Bioactive Materials (R. Baker, ed.). Academic Press, New York, 1980, pp. 19-43. [Pg.118]

Since the purpose of this book is to describe applications of biodegradable polymers to drug delivery systems, particularly from the perspective of the materials employed, the approach taken in this chapter has been to focus on the natural biodegradable polymers which have been used most extensively as matrices for the delivery of drugs. Consideration was also given to the fact that collagen has not been the subject of any recent reviews. [Pg.233]

Oppenheim, R. C., in Drug Delivery Systems Characteristics and Biomedical Applications (R. L. Juliano, ed.), Oxford University Press, New York, 1980. [Pg.255]

The nanostructured molecular arrangements from DNA developed by Seeman may find applications as biological encapsulation and drug-delivery systems, as artificial multienzymes, or as scaffolds for the self-assembling nanoscale fabrication of technical elements. Moreover, DNA-protein conjugates may be anticipated as versatile building blocks in the fabrication of multifunctional supramolecular devices and also as highly functional-... [Pg.423]

Because these types of polymeric matrix systems are the simplest to design and the easiest to obtain approval by the Food and Drug Administration, they have been the most extensively studied in the past two decades. Numerous polymers have been evaluated for these types of drug delivery systems and although it would be impractical to present each of these polymers and its specific application to drug delivery, this chapter will review in general the types of polymers used as matrices for drug delivery (1-4). [Pg.18]

Historically, the oral route of administration has been used the most for both conventional and novel drug-delivery systems. There are many obvious reasons for this, not the least of which would include acceptance by the patient and ease of administration. The types of sustained- and controlled-release systems employed for oral administration include virtually every currently known theoretical mechanism for such application. This is because there is more flexibility in dosage design, since constraints, such as sterility and potential damage at the site of administration, axe minimized. Because of this, it is convenient to discuss the different types of dosage forms by using those developed for oral administration as initial examples. [Pg.505]

Controlled Release Osmotic Drug Delivery Systems for Oral Applications... [Pg.424]

In addition to solvent uses, esters of lactic acid can be used to recover pure lactic acid via hydrolysis, which in-tum is used to make optically active dilactide and subsequently polylactic acid used for drag delivery system.5 This method of recovery for certain lactic acid applications is critical in synthesis of medicinal grade polymer because only optically active polymers with low Tg are useful for drug delivery systems. Lactic acid esters themselves can also be directly converted into polymers, (Figure 1), although the commercial route proceeds via ring-opening polymerization of dilactide. [Pg.374]

Despite the evidence for the cytotoxicity of CNTs, there are an increasing number of published studies that support the potential development of CNT-based biomaterials for tissue regeneration (e.g., neuronal substrates [143] and orthopedic materials [154—156]), cancer treatment [157], and drug/vaccine delivery systems [158, 159]. Most of these applications will involve the implantation and/or administration of such materials into patients as for any therapeutic or diagnostic agent used, the toxic potential of the CNTs must be evaluated in relation to their potential benefits [160]. For this reason, detailed investigations of the interactions between CNTs/CNT-based implants and various cell types have been carried out [154, 155, 161]. A comprehensive description of such results, however, is beyond the scope of this chapter. Extensive reviews on the biocompatibility of implantable CNT composite materials [21, 143, 162] and of CNT drug-delivery systems [162] are available. [Pg.198]

Poly-j3-malate is readily degraded completely to L-malic acid under both acid and base conditions [108], and it can also be hydrolyzed by enzymes within the cell [105,106]. Recently, several bacteria were isolated which were able to utilize poly-/i-malate as sole carbon source for growth [109]. Because the polymer is biodegradable and bioadsorbable, it is of considerable interest for pharmaceutical applications, especially in controlled-release drug delivery systems [97,98]. Chemical routes to poly-/ -malate are expected to provide materials with various properties [110]. [Pg.77]

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