Prevent

prevention

Water generation process & microbial contamination

The prevention of a microbial contamination is crucial within the water generation for the pharmaceutical industry. But how can we persistently prevent such? By understanding the process and thus being able to estimate the contribution of the risk for a microbial contamination for each individual process step. The design of the plant and the maintenance procedures are the two crucial aspects. We need to understand where the germs come from, therefore it is crucial to know how the entire water generation process is structured.

As the EU GMP Annex I states: "... The sterility test applied to the finished product should only be regarded as the last in a series of critical control measures by which sterility is assured. It cannot be used to assure sterility of a product that does not meet its design, procedural or validation parameters. The test should be validated for the product concerned..."

The water generation process in 3 steps

1. Pre-treatment of the raw water

2. Purification

3. Distribution and storage (PW or WFI)

For every step, the contribution to the risk of microbial contamination must be identified. This also applies to maintenance and repair activities. BWT has designed their instruments considering all aspects like minimized dead volumes, sanitizable components, and e.g. special regeneration procedures for the softener to avoid dead zones.

Learn more about the individual water generation steps and their contribution to the risk of microbial contamination. With a deeper understanding of water generation, your CCS becomes all-encompassing. Thus, the respective contributions to the risk of microbial contamination can also be identified. This also includes maintenance and repair activities. So the actual question is...

Where do germs come from?

To guarantee highest microbial safety, regular preventive or better predictive maintenance is recommended. BWT helps you with this.

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Pre-Treatment

Various water parameters influence the effectiveness and efficiency of a PW and WFI generation system. Factors such as particles, hardness, chlorination, and other characteristics of the raw water need to be considered when designing a pharmaceutical water generator.

There are several pre-treatment procedures available, such as Softener, Filtering, Antiscalant, and Bisulfite. The softener is broadly used in the pre-treatment process to reduce the concentration of hardness minerals (such as calcium and magnesium) to guarantee that the downstream water treatment processes, in particular the reverse osmosis can operate efficiently. As an alternative antiscalant dosing may replace the softener by increasing the solubility of critical minerals.

RISK

Important to consider is the fact that due to the design of a softener or filters, it is obvious that the level of bioburden rather increases than decreases in this process step. The growth conditions for microorganisms are very good with high nutrient and large surface areas of the resin or filters.

Even if the level of microorganisms before the RO membrane does not necessarily have a huge impact on the final product since the RO is a very effective barrier for bacteria, microbial load may influence all further process steps and may cause high endotoxin or TOC values. The only way to combat the microbial load is frequent sanitization of the softener, short regeneration intervals and/or filter replacement.

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Water Purification

The water purification process in cold systems is based on 3 main steps:

1. Reverse Osmosis (RO)

RO is the first process step towards purified water (PW) or water for injection (WFI) that changes the release relevant parameters like conductivity, total organic carbon (TOC) and bioburden. RO can either be applied as single or double pass, depending on the system setup and raw water composition. However, due to the design and functionality of the RO the concentration side of the RO always shows a very high bioburden and mineral concentration. Even if the RO is a very effective barrier, it’s not a 100% barrier. Membrane degassing and NaOH dosage are methods used to get rid of CO2 since it will increase the conductivity and influence the efficiency of the EDI.

2. Electrodeionisation (EDI)

EDI is used as a further purification step. It is a combination of separation of ions by applying an electric field, ion exchange resin and membrane separation. The ions pass through a semi-permeable membrane under the influence of an electrical field. The SEPTRON is not a mechanical barrier for microorganisms but due to the chemical conditions (pH –Gradient) it further reduces microbial burden.

3. Ultrafiltration (UF)

UF is the final step of the water purification process. It holds back particles, microorganisms or endotoxins.

RISK

Each purification step bears a risk for microbial contamination by either malfunction or insufficient maintenance procedures. Monitoring of the function can be done by measuring physical, chemical or microbial parameters. E.g. integrity of membrane systems can be monitored by measuring differential pressure or conductivity. Integrity monitoring in terms of microbial contamination risk is not sufficiaent since minimal “leakages” in membranes may have a minimum effect on physical or chemical parameters but are kind of an open door for microorganisms. Consequently, a comprehensive concept for sanitization and monitoring is crucial for process control.

storage and distribution

PW or WFI must be distributed from the water generator to the point of use. For storage and distribution, there are several strategies to ensure and maintain the quality.

Hot storage
Continuous Electrolytic Ozonization

Risk

The main contamination risks in storage and distribution are the storage tanks (ventilation, stagnant water) and the point of use itself. Filter quality and maintenance as well as procedures (SOP’s) for sampling is extremely important. The majority of contamination cases are due to inadequate SOP’s for sampling or handling failures.

Usually, the risk of contamination is small either by hot storage or permanent application of ozone. Anyway, authorities require proof of the microbial load by frequent sampling and analyzing.