Your search keyword '"physiologically-based biopharmaceutics modeling (pbbm)"' showing total 7 results

1. Oral Absorption from Surfactant-Based Drug Formulations: The Impact of Molecularly Dissolved Drug on Bioavailability.

Author

Holzem, Florentin Lukas, Parrott, Neil, Petrig Schaffland, Jeannine, Brandl, Martin, Bauer-Brandl, Annette, and Stillhart, Cordula

Subjects

*SODIUM dodecyl sulfate, *ORAL drug administration, *DRUG bioavailability, *DOSAGE forms of drugs, *BIOPHARMACEUTICS, *DRUG solubility, *SUPERSATURATION

Abstract

Enabling drug formulations are often required to ensure sufficient absorption after oral administration of poorly soluble drugs. While these formulations typically increase the apparent solubility of the drug, it is widely acknowledged that only molecularly dissolved, i.e., free fraction of the drug, is prone for direct absorption, while colloid-associated drug does not permeate to the same extent. In the present study, we aimed at comparing the effect of molecularly and apparently (i.e., the sum of molecularly and colloid-associated drug) dissolved drug concentrations on the oral absorption of a poorly water-soluble drug compound, Alectinib. Mixtures of Alectinib and respectively 50 %, 25 %, 12.5 %, and 3 % sodium lauryl sulfate (SLS) relative to the dose were prepared and small-scale dissolution tests were performed under simulated fed and fasted state conditions. Both the molecularly and apparently dissolved drug concentrations were assessed in parallel using microdialysis and centrifugation/filtration sampling, respectively. The data served as the basis for an in vitro-in vivo correlation (IVIVC) and as input for a GastroPlusTM physiologically-based biopharmaceutics model (PBBM). It was shown that with increasing the content of SLS the apparently dissolved drug in FeSSIF and FaSSIF increased to a linear extent and thus, the predicted in vivo performance of the 50 % SLS formulation, based on apparently dissolved drug, would outperform all other formulations. Against common expectation, however, the free (molecularly dissolved) drug concentrations were found to vary with SLS concentrations as well, yet to a minor extent. A systematic comparison of solubilized and free drug dissolution patterns at different SLS contents of the formulations and prandial states allowed for interesting insights into the complex dissolution-/supersaturation-, micellization-, and precipitation-behavior of the formulations. When comparing the in vitro datasets with human pharmacokinetic data from a bioequivalence study, it was shown that the use of molecularly dissolved drug resulted in an improved IVIVC. By incorporating the in vitro dissolution datasets into the GastroPlusTM PBBM, the apparently dissolved drug concentrations resulted in both, a remarkable overprediction of plasma concentrations as well as a misprediction of the influence of SLS on systemic exposure. In contrast, by using the molecularly dissolved drug (i.e., free fraction) as the model input, the predicted plasma concentration-time profiles were in excellent agreement with observed data for all formulations under both fed and fasted conditions. By combining an advanced in vitro assessment with PBBM, the present study confirmed that only the molecularly dissolved drug, and not the colloid-associated drug, is available for direct absorption. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

2. The emerging role of physiologically-based pharmacokinetic/biopharmaceutics modeling in formulation development

Author

Cvijić Sandra, Ignjatović Jelisaveta, Parojčić Jelena, and Ibrić Svetlana

Subjects

physiologically-based pharmacokinetic modeling (pbpk), physiologically-based biopharmaceutics modeling (pbbm), model informed drug development (midd), drug bioperformance, Pharmacy and materia medica, RS1-441

Abstract

Computer-based (in silico) modeling & simulation tools have been embraced in different fields of pharmaceutics for a variety of applications. Among these, physiologically-based pharmacokinetic/biopharmaceutics modeling (PBPK/PBBM) emerged as a particularly useful tool in formulation development. PBPK/PBBM facilitated strategies have been increasingly evaluated over the past few years, as demonstrated by several reports from the pharmaceutical industry, and a number of research and review papers on this subject. Also, the leading regulatory authorities have recently issued guidance on the use of PBPK modeling in formulation design. In silico PBPK models can comprise different dosing routes (oral, intraoral, parenteral, inhalation, ocular, dermal etc.), although the majority of published examples refer to modeling of oral drugs performance. In order to facilitate the use of PBPK modeling tools, a couple of companies have launched commercially available software such as GastroPlus™, Simcyp™ PBPK Simulator and PK-Sim®. This paper highlights various application fields of PBPK/PBBM modeling, along with the basic principles, advantages and limitations of this approach, and provides relevant examples to demonstrate the practical utility of modeling & simulation tools in different stages of formulation development.

Published

2021

3. Application of the Gastrointestinal Simulator (GIS) Coupled with In Silico Modeling to Measure the Impact of Coca-Cola® on the Luminal and Systemic Behavior of Loratadine (BCS Class 2b)

Author

Bart Hens, Marival Bermejo, Patrick Augustijns, Rodrigo Cristofoletti, Gregory E. Amidon, and Gordon L. Amidon

Subjects

biopharmaceutics classification system (BCS), low aqueous solubility, oral bioavailability, oral drug absorption, in silico modeling, biopredictive dissolution testing, physiologically-based biopharmaceutics modeling (PBBM), Pharmacy and materia medica, RS1-441

Abstract

In the present work, we explored if Coca-Cola® had a beneficial impact on the systemic outcome of the weakly basic drug loratadine (Wal-itin®, immediate-release formulation, 10 mg, generic drug product). To map the contribution of underlying physiological variables that may positively impact the intestinal absorption of loratadine, a multi-compartmental and dynamic dissolution device was built, namely the Gastrointestinal Simulator (GIS). The luminal behavior of one immediate-release (IR) tablet of 10 mg of loratadine was tested under four different fasted state test conditions in the GIS: (i) with 250 mL of water and applying a predetermined gastric half-life (t1/2,G) of 15 min; (ii) with 250 mL of water and applying a t1/2,G of 30 min; (iii) with 250 mL of Coca-Cola® and a t1/2,G of 15 min; (iv) with 250 mL of Coca-Cola® and a t1/2,G of 30 min. After initiating the experiments, solution concentrations and solubility were measured in the withdrawn samples, and pH was monitored. To address the impact of the present CO2 in Coca-Cola® on the disintegration time of the tablet, additional disintegration experiments were performed in a single-vessel applying tap water and sparkling water as dissolution media. These experiments demonstrated the faster disintegration of the tablet in the presence of sparkling water, as the present CO2 facilitates the release of the drug. The buffer capacity of Coca-Cola® in the presence of FaSSGF was 4-fold higher than the buffer capacity of tap water in the presence of FaSSGF. After performing the in vitro experiments, the obtained results were used as input for a two-compartmental pharmacokinetic (PK) modeling approach to predict the systemic concentrations. These simulations pointed out that (i) the present CO2 in Coca-Cola® is responsible for the enhancement in drug release and dissolution and that (ii) a delay in gastric emptying rate will sustain the supersaturated concentrations of loratadine in the intestinal regions of the GI tract, resulting in an enhanced driving force for intestinal absorption. Therefore, co-administration of loratadine with Coca-Cola® will highly likely result in an increased systemic exposure compared to co-administration of loratadine with tap water. The mechanistic insights that were obtained from this work will serve as a scientific basis to evaluate the impact of Coca-Cola® on the systemic exposure of weakly basic drugs for patients on acid-reducing agents in future work.

Published

2020

4. Uloga fiziološki-zasnovanog farmakokinetičkog/biofarmaceutskog modelovanja u razvoju farmaceutskih preparata

Author

Svetlana Ibrić, Sandra Cvijić, Jelisaveta Ignjatović, and Jelena Parojčić

Subjects

Physiologically based pharmacokinetic modelling, Computer science, physiologically-based biopharmaceutics modeling (PBBM), Pharmaceutical Science, 02 engineering and technology, 030226 pharmacology & pharmacy, model informed drug development (MIDD), Physiologically-based pharmacokinetic modeling (PBPK), 03 medical and health sciences, Pharmacy and materia medica, 0302 clinical medicine, bioperformanse lekova, physiologically-based pharmacokinetic modeling (pbpk), physiologically-based biopharmaceutics modeling (pbbm), model zasnovan razvoj lekova (MIDD), Pharmaceutical industry, Pharmacology, business.industry, Management science, Biopharmaceutics, drug bioperformance, 021001 nanoscience & nanotechnology, RS1-441, fiziološki zasnovano farmakokinetičko modelovanje (PBPK), fiziološki zasnovano biofarmaceutsko modelovanje (PBBM), 0210 nano-technology, business, model informed drug development (midd)

Abstract

Computer-based (in silico) modeling & simulation tools have been embraced in different fields of pharmaceutics for a variety of applications. Among these, physiologically-based pharmacokinetic/biopharmaceutics modeling (PBPK/PBBM) emerged as a particularly useful tool in formulation development. PBPK/PBBM facilitated strategies have been increasingly evaluated over the past few years, as demonstrated by several reports from the pharmaceutical industry, and a number of research and review papers on this subject. Also, the leading regulatory authorities have recently issued guidance on the use of PBPK modeling in formulation design. In silico PBPK models can comprise different dosing routes (oral, intraoral, parenteral, inhalation, ocular, dermal etc.), although the majority of published examples refer to modeling of oral drugs performance. In order to facilitate the use of PBPK modeling tools, a couple of companies have launched commercially available software such as GastroPlus™, Simcyp™ PBPK Simulator and PK-Sim®. This paper highlights various application fields of PBPK/PBBM modeling, along with the basic principles, advantages and limitations of this approach, and provides relevant examples to demonstrate the practical utility of modeling & simulation tools in different stages of formulation development. Računarski podržano (in silico) modelovanje se danas koristi u različitim oblastima farmaceutskih nauka, sa širokom paletom primene. Kao jedan od in silico alata, fiziološki zasnovano farmakokinetičko/biofarmaceutsko modelovanje (PBPK/PBBM) se pokazalo posebno korisnim u razvoju farmaceutskih preparata. Strategije zasnovane na PBPK/PBBM modelovanju se poslednjih godina sve više razmatraju, što se vidi iz izveštaja farmaceutskih kompanija i velikog broja publikovanih istraživačkih i revijalnih radova na ovu temu. Takođe, vodeće regulatorne agencije su nedavno izdale vodiče koji se odnose na primenu PBPK modelovanja u razvoju farmaceutskih preparata. In silico PBPK modelovanje je primenjivo za različite puteve primene leka (peroralni, (intra)oralni, parenteralni, inhalacioni, okularni, dermalni itd), mada se najveći broj primera iz literature odnosi na modelovanje bioperformansi peroralno primenjenih lekova. Kako bi olakšale primenu PBPK modelovanja, nekoliko kompanija je razvilo komercijalno dostupne programske pakete, kao što su GastroPlus™, Simcyp™ PBPK Simulator i PK-Sim®. U ovom radu su istaknute različite mogućnosti primene PBPK/PBBM modelovanja, uključujući osnovne principe, prednosti i ograničenja. Takođe, prikazani su odgovarajući primeri koji opisuju praktičnu primenu modelovanja i simulacija u različitim fazama razvoja leka.

Published

2021

5. The emerging role of physiologically-based pharmacokinetic/biopharmaceutics modeling in formulation development

Author

Cvijić, Sandra, Cvijić, Sandra, Ignjatović, Jelisaveta, Parojčić, Jelena, Ibrić, Svetlana, Cvijić, Sandra, Cvijić, Sandra, Ignjatović, Jelisaveta, Parojčić, Jelena, and Ibrić, Svetlana

Abstract

Computer-based (in silico) modeling & simulation tools have been embraced in different fields of pharmaceutics for a variety of applications. Among these, physiologically-based pharmacokinetic/biopharmaceutics modeling (PBPK/PBBM) emerged as a particularly useful tool in formulation development. PBPK/PBBM facilitated strategies have been increasingly evaluated over the past few years, as demonstrated by several reports from the pharmaceutical industry, and a number of research and review papers on this subject. Also, the leading regulatory authorities have recently issued guidance on the use of PBPK modeling in formulation design. In silico PBPK models can comprise different dosing routes (oral, intraoral, parenteral, inhalation, ocular, dermal etc.), although the majority of published examples refer to modeling of oral drugs performance. In order to facilitate the use of PBPK modeling tools, a couple of companies have launched commercially available software such as GastroPlus™, Simcyp™ PBPK Simulator and PK-Sim®. This paper highlights various application fields of PBPK/PBBM modeling, along with the basic principles, advantages and limitations of this approach, and provides relevant examples to demonstrate the practical utility of modeling & simulation tools in different stages of formulation development., Računarski podržano (in silico) modelovanje se danas koristi u različitim oblastima farmaceutskih nauka, sa širokom paletom primene. Kao jedan od in silico alata, fiziološki zasnovano farmakokinetičko/biofarmaceutsko modelovanje (PBPK/PBBM) se pokazalo posebno korisnim u razvoju farmaceutskih preparata. Strategije zasnovane na PBPK/PBBM modelovanju se poslednjih godina sve više razmatraju, što se vidi iz izveštaja farmaceutskih kompanija i velikog broja publikovanih istraživačkih i revijalnih radova na ovu temu. Takođe, vodeće regulatorne agencije su nedavno izdale vodiče koji se odnose na primenu PBPK modelovanja u razvoju farmaceutskih preparata. In silico PBPK modelovanje je primenjivo za različite puteve primene leka (peroralni, (intra)oralni, parenteralni, inhalacioni, okularni, dermalni itd), mada se najveći broj primera iz literature odnosi na modelovanje bioperformansi peroralno primenjenih lekova. Kako bi olakšale primenu PBPK modelovanja, nekoliko kompanija je razvilo komercijalno dostupne programske pakete, kao što su GastroPlus™, Simcyp™ PBPK Simulator i PK-Sim®. U ovom radu su istaknute različite mogućnosti primene PBPK/PBBM modelovanja, uključujući osnovne principe, prednosti i ograničenja. Takođe, prikazani su odgovarajući primeri koji opisuju praktičnu primenu modelovanja i simulacija u različitim fazama razvoja leka.

Published

2021

6. Application of the Gastrointestinal Simulator (GIS) Coupled with In Silico Modeling to Measure the Impact of Coca-Cola(R)on the Luminal and Systemic Behavior of Loratadine (BCS Class 2b)

Author

Rodrigo Cristofoletti, Marival Bermejo, Bart Hens, Gordon L. Amidon, and Gregory E. Amidon

Subjects

Gastric emptying, Chemistry, lcsh:RS1-441, Pharmaceutical Science, physiologically-based biopharmaceutics modeling (PBBM), Loratadine, Article, Intestinal absorption, Bioavailability, in silico modeling, oral drug absorption, lcsh:Pharmacy and materia medica, Tap water, Pharmacokinetics, oral bioavailability, biopharmaceutics classification system (BCS), low aqueous solubility, medicine, Solubility, biopredictive dissolution testing, Dissolution, Simulation, medicine.drug

Abstract

In the present work, we explored if Coca-Cola&reg, had a beneficial impact on the systemic outcome of the weakly basic drug loratadine (Wal-itin&reg, immediate-release formulation, 10 mg, generic drug product). To map the contribution of underlying physiological variables that may positively impact the intestinal absorption of loratadine, a multi-compartmental and dynamic dissolution device was built, namely the Gastrointestinal Simulator (GIS). The luminal behavior of one immediate-release (IR) tablet of 10 mg of loratadine was tested under four different fasted state test conditions in the GIS: (i) with 250 mL of water and applying a predetermined gastric half-life (t1/2,G) of 15 min, (ii) with 250 mL of water and applying a t1/2,G of 30 min, (iii) with 250 mL of Coca-Cola&reg, and a t1/2,G of 15 min, (iv) with 250 mL of Coca-Cola&reg, and a t1/2,G of 30 min. After initiating the experiments, solution concentrations and solubility were measured in the withdrawn samples, and pH was monitored. To address the impact of the present CO2 in Coca-Cola&reg, on the disintegration time of the tablet, additional disintegration experiments were performed in a single-vessel applying tap water and sparkling water as dissolution media. These experiments demonstrated the faster disintegration of the tablet in the presence of sparkling water, as the present CO2 facilitates the release of the drug. The buffer capacity of Coca-Cola&reg, in the presence of FaSSGF was 4-fold higher than the buffer capacity of tap water in the presence of FaSSGF. After performing the in vitro experiments, the obtained results were used as input for a two-compartmental pharmacokinetic (PK) modeling approach to predict the systemic concentrations. These simulations pointed out that (i) the present CO2 in Coca-Cola&reg, is responsible for the enhancement in drug release and dissolution and that (ii) a delay in gastric emptying rate will sustain the supersaturated concentrations of loratadine in the intestinal regions of the GI tract, resulting in an enhanced driving force for intestinal absorption. Therefore, co-administration of loratadine with Coca-Cola&reg, will highly likely result in an increased systemic exposure compared to co-administration of loratadine with tap water. The mechanistic insights that were obtained from this work will serve as a scientific basis to evaluate the impact of Coca-Cola&reg, on the systemic exposure of weakly basic drugs for patients on acid-reducing agents in future work.

Published

2020

7. Application of the Gastrointestinal Simulator (GIS) Coupled with In Silico Modeling to Measure the Impact of Coca-Cola® on the Luminal and Systemic Behavior of Loratadine (BCS Class 2b).

Author

Hens, Bart, Bermejo, Marival, Cristofoletti, Rodrigo, Amidon, Gregory E., and Amidon, Gordon L.

Subjects

*DRINKING water, *INTESTINAL absorption, *LORATADINE, *DRUG solubility, *PHARMACOKINETICS, *GENERIC products, *PYLORUS, *INTESTINES

Abstract

In the present work, we explored if Coca-Cola® had a beneficial impact on the systemic outcome of the weakly basic drug loratadine (Wal-itin®, immediate-release formulation, 10 mg, generic drug product). To map the contribution of underlying physiological variables that may positively impact the intestinal absorption of loratadine, a multi-compartmental and dynamic dissolution device was built, namely the Gastrointestinal Simulator (GIS). The luminal behavior of one immediate-release (IR) tablet of 10 mg of loratadine was tested under four different fasted state test conditions in the GIS: (i) with 250 mL of water and applying a predetermined gastric half-life (t1/2,G) of 15 min; (ii) with 250 mL of water and applying a t1/2,G of 30 min; (iii) with 250 mL of Coca-Cola® and a t1/2,G of 15 min; (iv) with 250 mL of Coca-Cola® and a t1/2,G of 30 min. After initiating the experiments, solution concentrations and solubility were measured in the withdrawn samples, and pH was monitored. To address the impact of the present CO2 in Coca-Cola® on the disintegration time of the tablet, additional disintegration experiments were performed in a single-vessel applying tap water and sparkling water as dissolution media. These experiments demonstrated the faster disintegration of the tablet in the presence of sparkling water, as the present CO2 facilitates the release of the drug. The buffer capacity of Coca-Cola® in the presence of FaSSGF was 4-fold higher than the buffer capacity of tap water in the presence of FaSSGF. After performing the in vitro experiments, the obtained results were used as input for a two-compartmental pharmacokinetic (PK) modeling approach to predict the systemic concentrations. These simulations pointed out that (i) the present CO2 in Coca-Cola® is responsible for the enhancement in drug release and dissolution and that (ii) a delay in gastric emptying rate will sustain the supersaturated concentrations of loratadine in the intestinal regions of the GI tract, resulting in an enhanced driving force for intestinal absorption. Therefore, co-administration of loratadine with Coca-Cola® will highly likely result in an increased systemic exposure compared to co-administration of loratadine with tap water. The mechanistic insights that were obtained from this work will serve as a scientific basis to evaluate the impact of Coca-Cola® on the systemic exposure of weakly basic drugs for patients on acid-reducing agents in future work. [ABSTRACT FROM AUTHOR]

Published

2020