Assessment of Moisture Permeability and Closure Systems of High Density Polyethylene Plastic Bottles Used as Primary Packaging Containers for Moisture Sensitive Medicines ()
Received 18 April 2016; accepted 8 August 2016; published 11 August 2016
1. Introduction
The packaging process of a pharmaceutical product is aimed at making sure that the quality of the finished product is preserved and hence the drug product of acceptable quality gets to the end user. Hence, packaging should preserve stability and quality of medicinal products and protects them against all forms of spoilage and tampering [1] .
High density polyethylene bottles are used in a variety of applications and industries where excellent impact resistance, high tensile strength, low moisture absorption and chemical and corrosion resistance properties are required [2] .
For pharmaceutical solid oral dosage forms, it is well recognized that the most common cause for a packaged product failing to meet its specification is its instability, as a result of “moisture uptake” [3] . The failure is usually related to out-of-specification or out-of-range values in any or combination of the following quality attri- butes: assay, product degradants, dissolution rate, and other physical properties [4] . Pharmaceutical solid oral dosage forms are typically packaged in plastic bottles, thermoformed plastic blisters, or cold-formed aluminum blisters. These container closure systems are sealed either by compression-fit between a hard surface and a soft surface or by application of heat to an adhesive layer of polymers [5] . They are considered semi-permeable packages and therefore the moisture barrier properties need to be characterized [6] .
All pharmaceutical products have to be packaged in containers that adhere to the prescribed pharmacopoeial standards particularly for solid dosage forms moisture appears to be critical as compared to other dosage forms such as liquids [7] . This indicates the need for a routine post-marketing surveillance to check whether the packaging materials of the products on the market suit the environment in which the product is to be accessed by the end users [8] .
2. Procedure
2.1. Sample Preparation
Containers from different suppliers named A, B and C and different batches (12 unit each) were selected for moisture permeation test where 2 containers where used as controls [9] .
All the containers were stored at 75% ± 3% relative humidity and a temperature of 23 ± 2 degrees in humidity climatic chamber for 14 days [10] [11] .
2.2. Material
The sample containers were collected from different suppliers and coded as supplier A, B and C. Calcium chloride (4 - 8 mesh) as desiccant and sodium chloride―RANKEM (RFCL), Okhla industrial area, New Delhi (INDIA) were used for moisture determination.
2.3. Sample Analysis
2.3.1. Tested Parameters
Two parameters were determined in this study, these includes, identifications and moisture permeability of the High density polyethylene plastic bottles.
2.3.2. Moisture Permeation
The sample containers were subjected to humidity controlled chamber at 75% ± 3% relative humidity and a temperature of 23˚C ± 2˚C for 14 days, later moisture uptake was determined for each container.
2.3.3. Fourier-Transform Infrared
The transmittance of the plastic was determined by Fourier Transform Infrared (FT-IR).
3. Results and Discussion
It can be seen in the results indicated in Figure 1, containers supplied by supplier C were incorrectly regarded as “Tight containers” as their average rate of moisture permeability was not within the range specified in the USP 37 <671> whereas containers supplied by supplier A and B were correctly regarded as “Tight containers” as their average rate of moisture permeability values were within the range specified in the USP Pharmacopeia.
All of these spectra in the region above 1500 (>1500) are comparable to the HDPE reference spectrum in Figure 2. In the fingerprint region to the right-hand side of the diagram in Figure 2 (from about 1500 to 500 cm−1) the reference HDPE spectrum is different from the spectra for container A, B and C. These are mainly due to all manner of bending vibrations within the molecule. The importance of the fingerprint region is that each different compound produces a different pattern of troughs in this part of the spectrum.
This indicates the fact that the reference HDPE is different from the HDPE containers collected from the market. It can be observed in Figure 2, spectra of plastic container from supplier A and C over-laid together with the reference HDPE spectrum show a remarkable absorption pattern difference indicating the plausible differences in chemical composition; however, this difference is largely pronounced in infra-red spectrum of HDPE containers from supplier C. This could explain as to why the HDPE containers from supplier C were failing the moisture permeability test.
4. Conclusions
It is of public interest to test the integrity of the container closure systems as it was found in this study that there were some medicinal containers on the market which were claimed to be “Tight containers” whereas practically found not to be the case. From the three Suppliers of containers tested in this study, two suppliers (A and B) met the USP Pharmacopoeia specifications and the containers were correctly regarded as “Tight containers” while one, supplier C did not, and the containers were regarded as “Not Tight” (Figure 1). Hence, containers from sup-
Figure 1. A bar chart of rate of moisture permeability for ten tested containers from different suppliers i.e coded supplier A, B and C.
Figure 2. Spectra of plastic container from supplier A and C over-laid together with the reference HDPE spectrum, all scanned from 4000 - 400 cm−1 with KBr as a detector and a total of 16 scans were collected.
plier A and B can be used as primary packaging containers for Lamivudine and Tenofovir Disoproxil Fumarate (TDF) Fixed Dose combination (FDC) as since Tenofovir Disoproxil Fumarate can be hydrolysed in the presence of moisture and hence regarded as a moisture sensitive drug which has to be packed in “Tight containers”.
It was generally found that the volume of the container had no effect on the results, as to whether regarding a container Tight or Not Tight since the Tight containers’ volume ranged from smallest (80 mL) to the largest being 150 mL.
From the infra-red spectra of HDPE bottles as compared to the reference HDPE spectrum it can be concluded that the infra-red spectrum of the container failing on closure system study does not differ significantly from the container passing on the same study and from the reference spectrum. This indicates clearly that failing on moisture permeability is not associated with the quality of material used but rather the integrity of the closure system.
Acknowledgements
We appreciate the support from action medeor, Tanzania and Germany,SIDA and MUHAS for financial support by providing the reagents and materials for the study. Also we acknowledge the technical contribution from members of staff of Pharmaceutical Research and Development Laboratory (Pharm R&D) Laboratory, MUHAS; Ms. Ruth Ng’wananogu and Ms. Bertha Francis, Mr. Edson Lutta and Mr. Mhando Maro.