Pharmaceutical Applications of Hot-Melt Extrusion: Part I
TL;DR: The pharmaceutical applications of hot-melt extrusion, including equipment, principles of operation, and process technology, are reviewed and the physicochemical properties of the resultant dosage forms are described.
Abstract: Interest in hot-melt extrusion techniques for pharmaceutical applications is growing rapidly with well over 100 papers published in the pharmaceutical scientific literature in the last 12 years. Hot-melt extrusion (HME) has been a widely applied technique in the plastics industry and has been demonstrated recently to be a viable method to prepare several types of dosage forms and drug delivery systems. Hot-melt extruded dosage forms are complex mixtures of active medicaments, functional excipients, and processing aids. HME also offers several advantages over traditional pharmaceutical processing techniques including the absence of solvents, few processing steps, continuous operation, and the possibility of the formation of solid dispersions and improved bioavailability. This article, Part I, reviews the pharmaceutical applications of hot-melt extrusion, including equipment, principles of operation, and process technology. The raw materials processed using this technique are also detailed and the physicochemical properties of the resultant dosage forms are described. Part II of this review will focus on various applications of HME in drug delivery such as granules, pellets, immediate and modified release tablets, transmucosal and transdermal systems, and implants.
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TL;DR: In this article, the authors investigated the effect of scale-up of a continuous process and its effect on the critical quality attributes (CQAs) of the end product of a drug.
2 citations
TL;DR: In this article , the degradation of enalapril maleate during hot-melt extrusion (HME) was investigated and a fast HPLC method was developed to quantify enalAPril maleates and possible degradation products, which revealed that the diketopiperazine derivative was the main degradation product.
Abstract: The aim of this research was the production of extrudates for the treatment of hypertension and heart failure and the investigation of the degradation of the peptidomimetic drug enalapril maleate (EM) during hot-melt extrusion (HME). A fast HPLC method was developed to quantify enalapril maleate and possible degradation products. Screening experiments revealed that the diketopiperazine derivative (Impurity D) was the main degradation product. Hot-melt extrusion of enalapril maleate with the polymer Soluplus® enabled extrusion at 100 °C, whereas a formulation with the polymer Eudragit® E PO could be extruded at only 70 °C. Extrusion at 70 °C prevented thermal degradation. A stabilizing molecular interaction between enalapril maleate and Eudragit® E PO was identified via FT-IR spectroscopy. Dissolution studies were carried out to study the influence of the formulation on the dissolution behavior of enalapril maleate. These promising results can be transferred to other thermo-sensitive and peptidomimetic drugs to produce extrudates which can be used, for instance, as feedstock material for the production of patient-specific dosage forms via Fused Deposition Modeling (FDM) 3D printing.
2 citations
01 Jan 2013
TL;DR: Quality-by-design (QbD) has become an essential part of modern pharmaceutical quality systems since it incorporates an enhanced product and process understanding and has the potential to replace traditional batch processes due to its continuous nature and ease of scale-up from laboratory scale to commercial scale.
Abstract: Hot-melt extrusion represents an efficient technology to formulate drugs with poor aqueous solubility into safe and effective drug delivery systems. The interest in this technology continues to grow as it is suitable for both high dose and potent low dose compounds. It is amenable to real-time monitoring and control of the consistency of the product with respect to content uniformity and crystalline conversion. Quality-by-design (QbD) has become an essential part of modern pharmaceutical quality systems since it incorporates an enhanced product and process understanding. It encourages real-time monitoring and control of critical material attributes and process parameters. The QbD paradigm can be easily incorporated into hot-melt processes. It has the potential to replace traditional batch processes due to its continuous nature and ease of scale-up from laboratory scale to commercial scale.
2 citations
TL;DR: The types of Extruder, solid dispersion and Application of the HME to the pharmaceutical industries are reviewed.
Abstract: The use of hot-melt extrusion (HME) within the pharmaceutical industry is steadily increasing, due to proven its ability to efficiently manufacture novel products. With the use of HME we can increase solubility and bioavailability of the API. HME has proven to be a robust method of producing numerous drug delivery systems like modified, controlled and targeted drug delivery systems. resulting improved bioavailability as well as taste masking of bitter active pharmaceutical ingredients (APIs). Hot-melt extrusion techniques are pragmatic in the manufacture of a variety of dosage forms and formulations such as granules, pellets, tablets, suppositories, implants, stents, transdermal systems and ophthalmic inserts. In This paper we review about the types of Extruder, solid dispersion and Application of the HME to the pharmaceutical industries.
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TL;DR: Compared to previous developments, the extrudates now offer a high flexibility combined with a large mechanical resilience, which will ease the handling and administration.
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References
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1,883 citations
Book•
01 Jan 1995
TL;DR: The authors provided the basic building blocks of polymer science and engineering by coverage of fundamental polymer chemistry and materials topics given in Chapters 1 through 7 and provided information on the exciting new materialsnow available and the emerging areas of technological growth that could motivate a new generation of scientists and engineers.
Abstract: From the Book:
PREFACE: At least dozens of good introductory textbooks on polymer science and engineering are now available. Why then has yet another book been written?
The decision was based on my belief that none of the available texts fully addresses the needs of students in chemical engineering. It is not that chemical engineers are a rare breed, but rather that they have special training in areas of thermodynamics and transport phenomena that is seldom challenged by texts designed primarily for students of chemistry or materials science. This has been a frustration of mine and of many of my students for the past 15 years during which I have taught an introductory course, Polymer Technology, to some 350 chemical engineering seniors. In response to this perceived need, I had written nine review articles that appeared in the SPE publication Plastics Engineering from 1982 to 1984. These served as hard copy for my students to supplement their classroom notes but fell short of a complete solution.
In writing this text, it was my objective to first provide the basic building blocks of polymer science and engineering by coverage of fundamental polymer chemistry and materials topics given in Chapters 1 through 7.
As a supplement to the traditional coverage of polymer thermodynamics, extensive discussion of phase equilibria, equation-of- state theories, and UNIFAC has been included in Chapter 3. Coverage of rheology, including the use of constitutive equations and the modeling of simple flow geometries, and the fundamentals of polymer processing operations are given in Chapter 11.
Finally, I wanted to provide information on the exciting new materialsnowavailable and the emerging areas of technological growth that could motivate a new generation of scientists and engineers. For this reason, engineering and specialty polymers are surveyed in Chapter 10 and important new applications for polymers in separations (membrane separations), electronics (conducting polymers), biotechnology (controlled drug release), and other specialized areas of engineering are given in Chapter 12. In all, this has been an ambitious undertaking and I hope that I have succeeded in at least some of these goals.
Although the intended audience for this text is advanced undergraduates and graduate students in chemical engineering, the coverage of polymer science fundamentals (Chapters 1 through 7) should be suitable for a semester course in a materials science or chemistry curriculum.
Chapters 8 through 10 intended as survey chapters of the principal categories of polymers commodity thermoplastics and fibers, network polymers (elastomers and thermosets), and engineering and specialty polymers may be included to supplement and reinforce the material presented in the chapters on fundamentals and should serve as a useful reference source for the practicing scientist or engineer in the plastics industry.
981 citations
TL;DR: A comparison of the carbonyl stretching region of γ indomethacin, known to form carboxylic acid dimers, with that of amorphous indometHacin indicated that the amorphously phase exists predominantly as dimers.
Abstract: Purpose. To study the molecular structure of indomethacin-PVP amorphous solid dispersions and identify any specific interactions between the components using vibrational spectroscopy.
904 citations
Book•
01 Jan 1988
TL;DR: In this article, the elastic properties of polymeric solids and their properties of rubber are discussed. But they focus on the structure of the molecule rather than the properties of the solids.
Abstract: Introduction. 1: Structure of the molecule. 2: Structure of polymeric solids. 3: The elastic properties of rubber. 4: Viscoelasticity. 5: Yield and fracture. 6: Reinforced polymers. 7: Forming. 8: Design. Further reading, Answers, Index
790 citations
TL;DR: Improved bioavailability was achieved again demonstrating the value of the technology as a drug delivery tool, with particular advantages over solvent processes like co-precipitation.
790 citations