Nothing
FormulR"
In FormulR: Comprehensive Tools for Drug Formulation Analysis and Visualization
knitr::opts_chunk$set(
collapse = TRUE,
comment = "#>"
)
Load necessary libraries
library(FormulR)
library(dplyr) # for data manipulation
library(ggplot2) # for data visualization
Introduction to Drug Formulation Analysis
Overview
Welcome to the Drug Formulation Analysis vignette! In this tutorial, we'll explore how to analyze simulated data related to drug formulation using R. We'll cover various aspects of statistical analysis, data visualization, interpretation of results, comparative analysis, and quality control tools commonly used in pharmaceutical research.
Simulated Data Generation
First, let's generate some simulated data to work with. Our dataset contains information on drug release, particle size, formulation type, viscosity, stability index, storage condition, pH, and drug content over time.
Simulated data with two levels of Formulation_Type and time points
formulation_data <- data.frame(
Time = seq(1, 100), # Assuming 100 time points
Excipient_Concentration = runif(100, min = 0, max = 1),
Drug_Release = rnorm(100, mean = 50, sd = 10),
Particle_Size = rnorm(100, mean = 100, sd = 20),
Formulation_Type = sample(c("Type A", "Type B"), 100, replace = TRUE),
Viscosity = rnorm(100, mean = 10, sd = 2),
Stability_Index = rnorm(100, mean = 95, sd = 5),
Storage_Condition = sample(c("Room", "Cold", "Warm"), 100, replace = TRUE),
pH = rnorm(100, mean = 7, sd = 0.5),
Drug_Content = rnorm(100, mean = 95, sd = 2)
)
Statistical Analysis
Let's start by conducting statistical analysis on our data. We'll perform ANOVA and regression analysis to explore relationships between variables.
# Statistical Analysis
anova_results <- anova_analysis(formulation_data)
regression_results <- regression_analysis(formulation_data)
hypothesis_test_results <- hypothesis_testing(formulation_data)
Data Visualization
Next, we'll visualize our data using scatterplots, histograms, and boxplots to gain insights into the distribution and relationships between variables.
# Data Visualization
scatterplot(formulation_data, x = "Excipient_Concentration", y = "Drug_Release")
histogram(formulation_data, x = "Particle_Size", bins = 20)
boxplot(formulation_data, x = "Formulation_Type", y = "Viscosity")
Interpretation of Results
We'll interpret the results obtained from our analyses, including summary statistics and confidence intervals.
# Interpretation of Results
summary_stats <- summary_statistics(formulation_data)
confidence_intervals <- confidence_intervals(formulation_data)
Comparative Analysis
We'll compare means and distributions across different formulation types and storage conditions to identify any significant differences.
# Interpretation of Results
# Comparative Analysis
compare_means(formulation_data, group_var = "Formulation_Type", response_var = "Stability_Index")
compare_distributions(formulation_data, group_var = "Storage_Condition", response_var = "Drug_Content")
Quality Control Tools
Finally, we'll use quality control tools such as control charts and batch variability analysis to monitor and assess the consistency and quality of our formulations.
# Quality Control Tools
control_chart(formulation_data, parameter = "pH")
batch_variability(formulation_data, parameter = "Drug_Content")
Try the FormulR package in your browser
Any scripts or data that you put into this service are public.
FormulR documentation built on June 22, 2024, 7:36 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
knitr::opts_chunk$set( collapse = TRUE, comment = "#>" )
Load necessary libraries
library(FormulR) library(dplyr) # for data manipulation library(ggplot2) # for data visualization
Introduction to Drug Formulation Analysis
Overview
Welcome to the Drug Formulation Analysis vignette! In this tutorial, we'll explore how to analyze simulated data related to drug formulation using R. We'll cover various aspects of statistical analysis, data visualization, interpretation of results, comparative analysis, and quality control tools commonly used in pharmaceutical research.
Simulated Data Generation
First, let's generate some simulated data to work with. Our dataset contains information on drug release, particle size, formulation type, viscosity, stability index, storage condition, pH, and drug content over time.
Simulated data with two levels of Formulation_Type and time points
formulation_data <- data.frame( Time = seq(1, 100), # Assuming 100 time points Excipient_Concentration = runif(100, min = 0, max = 1), Drug_Release = rnorm(100, mean = 50, sd = 10), Particle_Size = rnorm(100, mean = 100, sd = 20), Formulation_Type = sample(c("Type A", "Type B"), 100, replace = TRUE), Viscosity = rnorm(100, mean = 10, sd = 2), Stability_Index = rnorm(100, mean = 95, sd = 5), Storage_Condition = sample(c("Room", "Cold", "Warm"), 100, replace = TRUE), pH = rnorm(100, mean = 7, sd = 0.5), Drug_Content = rnorm(100, mean = 95, sd = 2) )
Statistical Analysis
Let's start by conducting statistical analysis on our data. We'll perform ANOVA and regression analysis to explore relationships between variables.
# Statistical Analysis anova_results <- anova_analysis(formulation_data) regression_results <- regression_analysis(formulation_data) hypothesis_test_results <- hypothesis_testing(formulation_data)
Data Visualization
Next, we'll visualize our data using scatterplots, histograms, and boxplots to gain insights into the distribution and relationships between variables.
# Data Visualization scatterplot(formulation_data, x = "Excipient_Concentration", y = "Drug_Release") histogram(formulation_data, x = "Particle_Size", bins = 20) boxplot(formulation_data, x = "Formulation_Type", y = "Viscosity")
Interpretation of Results
We'll interpret the results obtained from our analyses, including summary statistics and confidence intervals.
# Interpretation of Results summary_stats <- summary_statistics(formulation_data) confidence_intervals <- confidence_intervals(formulation_data)
Comparative Analysis
We'll compare means and distributions across different formulation types and storage conditions to identify any significant differences.
# Interpretation of Results # Comparative Analysis compare_means(formulation_data, group_var = "Formulation_Type", response_var = "Stability_Index") compare_distributions(formulation_data, group_var = "Storage_Condition", response_var = "Drug_Content")
Quality Control Tools
Finally, we'll use quality control tools such as control charts and batch variability analysis to monitor and assess the consistency and quality of our formulations.
# Quality Control Tools control_chart(formulation_data, parameter = "pH") batch_variability(formulation_data, parameter = "Drug_Content")
Try the FormulR package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.