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Looking inside the ‘black box’: freezing engineering for assuring quality of freeze-dried biopharmaceuticals

Research output: Contribution to conference - Without ISBN/ISSN Abstractpeer-review

Published

Standard

Looking inside the ‘black box’: freezing engineering for assuring quality of freeze-dried biopharmaceuticals. / Capozzi, Luigi; Arsiccio, Andrea; Pisano, Roberto.
2017. Abstract from 8th International Conference of International Society of Lyophilization - Freeze-Drying, La Habana, Cuba.

Research output: Contribution to conference - Without ISBN/ISSN Abstractpeer-review

Harvard

Capozzi, L, Arsiccio, A & Pisano, R 2017, 'Looking inside the ‘black box’: freezing engineering for assuring quality of freeze-dried biopharmaceuticals', 8th International Conference of International Society of Lyophilization - Freeze-Drying, La Habana, Cuba, 24/04/17 - 28/04/17.

APA

Capozzi, L., Arsiccio, A., & Pisano, R. (2017). Looking inside the ‘black box’: freezing engineering for assuring quality of freeze-dried biopharmaceuticals. Abstract from 8th International Conference of International Society of Lyophilization - Freeze-Drying, La Habana, Cuba.

Vancouver

Capozzi L, Arsiccio A, Pisano R. Looking inside the ‘black box’: freezing engineering for assuring quality of freeze-dried biopharmaceuticals. 2017. Abstract from 8th International Conference of International Society of Lyophilization - Freeze-Drying, La Habana, Cuba.

Author

Capozzi, Luigi ; Arsiccio, Andrea ; Pisano, Roberto. / Looking inside the ‘black box’: freezing engineering for assuring quality of freeze-dried biopharmaceuticals. Abstract from 8th International Conference of International Society of Lyophilization - Freeze-Drying, La Habana, Cuba.

Bibtex

@conference{4ad80894fe4b42c1a9cfe26aa38f6503,
title = "Looking inside the {\textquoteleft}black box{\textquoteright}: freezing engineering for assuring quality of freeze-dried biopharmaceuticals",
abstract = "The pharmaceutical industry is at a turning point of its history, shifting from a mass production of patented drugs to a more competitive, innovative and highly regulated market. In fact, the last few years has seen the rapid emergence of the industry of off-patented drugs and the increase of the requirements of quality, safety and efficiency set by regulatory authorities. In addition, in the next years, the production of personalized, {\textquoteleft}on-demand{\textquoteright}, drugs will replace completely the old, batch, technologies with more flexible systems and continuous processes (Byrn et al. 2015). As the future of the pharmaceutical industry is continuous manufacturing, also freeze-drying of pharmaceuticals needs to be converted to continuous and integrated into the production chain. In this perspective, the design of freezing step plays a central role to reach the more stringent requirements of quality, homogeneity and standardization of freeze-dried products (Barresi et al. 2009; Pisano et al. 2016). Both trial-and-error and black box approaches, that are widely used to design freeze-drying cycles, become not sufficient anymore. A new mindset toward research and development is required to open and look inside the {\textquoteleft}black box{\textquoteright}, in order to design freezing protocols that produce dried products with the desired final attributes, to predict its variability within a production and the losses due to undesired off-target products. Of course, the product structure is a key factor in the production of stable and valuable dried products, because it affects the stability of APIs, determines the drying and desorption rate and, finally, the appearance of the product, the residual moisture and the rehydration time. The objective of this work is to develop an innovative way for designing the freezing step in order to have a production of freeze-dried products with the desired attributes, and to have a good estimation of inter- and intra-vial heterogeneity. Our procedure consisted of coupling the distribution of nucleation temperature obtained from simple experimental tests with a detailed mathematical model of freezing. As case study, we compared the performances of two freezing protocols. ",
author = "Luigi Capozzi and Andrea Arsiccio and Roberto Pisano",
year = "2017",
language = "English",
note = "8th International Conference of International Society of Lyophilization - Freeze-Drying, ISLFD 2017 ; Conference date: 24-04-2017 Through 28-04-2017",

}

RIS

TY - CONF

T1 - Looking inside the ‘black box’: freezing engineering for assuring quality of freeze-dried biopharmaceuticals

AU - Capozzi, Luigi

AU - Arsiccio, Andrea

AU - Pisano, Roberto

PY - 2017

Y1 - 2017

N2 - The pharmaceutical industry is at a turning point of its history, shifting from a mass production of patented drugs to a more competitive, innovative and highly regulated market. In fact, the last few years has seen the rapid emergence of the industry of off-patented drugs and the increase of the requirements of quality, safety and efficiency set by regulatory authorities. In addition, in the next years, the production of personalized, ‘on-demand’, drugs will replace completely the old, batch, technologies with more flexible systems and continuous processes (Byrn et al. 2015). As the future of the pharmaceutical industry is continuous manufacturing, also freeze-drying of pharmaceuticals needs to be converted to continuous and integrated into the production chain. In this perspective, the design of freezing step plays a central role to reach the more stringent requirements of quality, homogeneity and standardization of freeze-dried products (Barresi et al. 2009; Pisano et al. 2016). Both trial-and-error and black box approaches, that are widely used to design freeze-drying cycles, become not sufficient anymore. A new mindset toward research and development is required to open and look inside the ‘black box’, in order to design freezing protocols that produce dried products with the desired final attributes, to predict its variability within a production and the losses due to undesired off-target products. Of course, the product structure is a key factor in the production of stable and valuable dried products, because it affects the stability of APIs, determines the drying and desorption rate and, finally, the appearance of the product, the residual moisture and the rehydration time. The objective of this work is to develop an innovative way for designing the freezing step in order to have a production of freeze-dried products with the desired attributes, and to have a good estimation of inter- and intra-vial heterogeneity. Our procedure consisted of coupling the distribution of nucleation temperature obtained from simple experimental tests with a detailed mathematical model of freezing. As case study, we compared the performances of two freezing protocols.

AB - The pharmaceutical industry is at a turning point of its history, shifting from a mass production of patented drugs to a more competitive, innovative and highly regulated market. In fact, the last few years has seen the rapid emergence of the industry of off-patented drugs and the increase of the requirements of quality, safety and efficiency set by regulatory authorities. In addition, in the next years, the production of personalized, ‘on-demand’, drugs will replace completely the old, batch, technologies with more flexible systems and continuous processes (Byrn et al. 2015). As the future of the pharmaceutical industry is continuous manufacturing, also freeze-drying of pharmaceuticals needs to be converted to continuous and integrated into the production chain. In this perspective, the design of freezing step plays a central role to reach the more stringent requirements of quality, homogeneity and standardization of freeze-dried products (Barresi et al. 2009; Pisano et al. 2016). Both trial-and-error and black box approaches, that are widely used to design freeze-drying cycles, become not sufficient anymore. A new mindset toward research and development is required to open and look inside the ‘black box’, in order to design freezing protocols that produce dried products with the desired final attributes, to predict its variability within a production and the losses due to undesired off-target products. Of course, the product structure is a key factor in the production of stable and valuable dried products, because it affects the stability of APIs, determines the drying and desorption rate and, finally, the appearance of the product, the residual moisture and the rehydration time. The objective of this work is to develop an innovative way for designing the freezing step in order to have a production of freeze-dried products with the desired attributes, and to have a good estimation of inter- and intra-vial heterogeneity. Our procedure consisted of coupling the distribution of nucleation temperature obtained from simple experimental tests with a detailed mathematical model of freezing. As case study, we compared the performances of two freezing protocols.

M3 - Abstract

T2 - 8th International Conference of International Society of Lyophilization - Freeze-Drying

Y2 - 24 April 2017 through 28 April 2017

ER -