We evaluated the LevMixer™ 10 L single-use mixing system for both visible and sub-visible particle generation over 24 h of high speed mixing, under extreme temperature conditions. Particle levels remained stable and well within USP <788> and Cytiva specifications, confirming the system’s suitability for particulate-sensitive applications like final fill.
Introduction
Particulate matter is a critical concern in single-use bioprocessing systems. Even small particles can compromise product purity and pose significant risks to the quality and safety of biopharmaceuticals. This is especially important in downstream processing steps like final fill, where no further filtration is feasible. At this stage, any particles introduced into the product stream cannot be removed and remain in the final product.
In this application note, we evaluate particle generation over time in the LevMixer™ 10 L single-use mixing system (Fig 1), which features a bearingless, magnetically levitated impeller. The aim was to determine whether the system produces visible and/or sub-visible particles during mixing under challenging conditions.
Fig 1. LevMixer™ 10 L single-use mixing system.
MATERIALS AND METHODS
Table 1. Equipment and materials used
| Item | Details |
| Mixing system | LevMixer™ 10 L single-use mixing system |
| Biocontainer | LevMixer™ 10 L single-use biocontainer bags |
| Liquid | Type-2 ultrapure water (prefiltered to 0.1 µm) |
| Liquid filter | Mini Kleenpak™ DJL 0.1 µm filter |
| Vent filter | Supor™ EKV Kleenpak™ capsule 0.1 µm vent filter |
| Temperature control unit | LAUDA Variocool VC 1200 NRTL |
| Sample containers | 500 mL PET PharmaTainers |
| Analysis system | Microscopic automated image analysis system |
| Test environment | Particle test laboratory |
Table 2. Experimental conditions and parameters
| Parameter | Details |
| Fluid | Type-2 ultrapure water (UPW) |
| Temperature (°C) | 21 (room temp), 40 (elevated), and 4 (cold), controlled via TCU |
| Runs | 3 runs at 21 °C (3 different batches), 1 run at 40 °C, 1 run at 4 °C |
| Mixing speed (rpm) | Up to 2900 |
| Mixing duration (h) | 24 |
| Liquid volume (L) | 5 (50% of maximum fill volume) |
| Biocontainer inflation | Yes, using manual hand pump to achieve 3D geometry |
| Sampling time points | T = 0 h (1 min), 2 h, 6 h, and 24 h |
| Sampling location | Biocontainer drain port |
| Sampling volume (mL) | 300 per time point |
| Analysis method | Microscopic automated image analysis (USP <788>, method 2) |
| Irradiation | Gamma-irradiated (25 to 50 kGy) |
We set up the LevMixer™ 10 L single-use mixing system hardware, and the installed the single-use biocontainer, following procedure from Cytiva’s published Instructions For Use (IFU).
Before filling the biocontainer, we flushed the filling assembly, containing a Mini Kleenpak™ DJL 0.1 µm liquid filter inline with 2 L of ultrapure water to hydrate the membrane and thoroughly rinse the fluid line. The single use biocontainer was then filled and mixed with 5 L of ultrapure water twice for five minutes to rinse the bag, minimize initial particle levels, and improve the accuracy of particle detection, even though our biocontainers meet USP <788> compliance.
To verify system integrity, we collected two control samples:
- One directly from the ultrapure water source.
- A second sample from the filling manifold, after filtration to ensure filter integrity.
The biocontainer was first inflated to its final 3D geometry using a manual hand pump through a Supor™ EKV Kleenpak™ 0.1 µm vent filter. It was then filled by weight with 5.4 ± 0.05 kg of ultrapure water (assuming a density of 1000 kg/m³), using a pre-hydrated Mini Kleenpak™ DJL liquid filter and a quick-fit connector. Mixing was initiated at maximum impeller speed and maintained for 24 hours under controlled temperature conditions. For the data points at 40 °C and 4 °C, gentle agitation was started overnight prior to full-speed mixing.
Sampling
We collected 300 mL samples from the mixing biocontainer, at four time points during mixing:
- Sample 1: T = 0 h (after 1 minute of mixing)
- Sample 2: T = 2 h
- Sample 3: T = 6 h
- Sample 4: T = 24 h
Before each sample collection, we flushed the sampling line with 100 g of bulk water from the mixer (discarded) to clear the line and eliminate any residual content from the previous sample. We then collected a 300 g sample. All samples were drawn by gravity through the biocontainer’s drain port while mixing was active. The targeted initial working volume of 5 L was obtained after the first sample was collected (T=0h).
Data processing, analysis and particle counting
We analyzed all water samples, including blanks, for sub-visible and visible particles according to the USP <788> count Method 2 (Microscopic particle count test). We determined the total particle counts by summing the particles detected in the initial 300 mL sample with those observed in three subsequent 200 mL flushes of the biocontainer. We used a new single use biocontainer for each sample.
To account for potential background contamination, we collected blank samples prior to each experiment and processed them identically to the test samples. These included:
- An aliquot drawn directly from the ultrapure water source.
- Three 200 mL flushes using the same water.
For each particle size category, we subtracted the sum of the particles counted in the blank from the sum of particles in the samples. This meant we took into consideration the potential particle presence in the ultrapure water. This was calculated as follows:
Total adjusted particle count = (∑ sample + flushes) – average (∑ blanks + flushes)
To compare particle levels over time, we normalized the data obtained based on the maximum count for the T = 24 h sample, which was considered as being the 100%, This approach allowed us to track particle trends across different batches and temperature conditions, while accounting for baseline variability.
Normalization was carried out as shown in the calculation below:
Where the:
- Particle count in sample corresponds to the individual particle counting for each sample time per experiment (batches 1, 2, and 3 at room temperature and runs at 4 °C and 40 °C) and particle size (≥ 10, ≥ 25 and ≥ 100 µm).
- Max particle count (T=24h) represents the particle count at T = 24 hours for the batch that exhibited the highest total, for each particle size category (≥ 10 µm, ≥ 25 µm, and ≥ 100 µm).
Results
Figs 2, 3, and 4 show the evolution of sub-visible and visible particles in the size categories ≥ 10 µm, ≥ 25 µm and ≥ 100 µm, respectively.
Fig 2. Evolution of sub-visible and visible particles in size category ≥ 10 µm in the LevMixer™ 10 L single-use mixing system over time, calculated in percentage and normalized based on the particles level in the sample T24h. RT = room temperature.
Fig 3. Evolution of sub-visible and visible particles in size category ≥ 25 µm in the LevMixer™ 10 L single-use mixing system over time, calculated in percentage and normalized based on the particles level in the sample T24h. RT = room temperature.
Fig 4. Evolution of sub-visible and visible particles in size category ≥ 100 µm in the LevMixer™ 10 L single-use mixing system over time, calculated in percentage and normalized based on the particles level in the sample T24h. RT = room temperature.
Key observations:
- Initial particle levels (T = 0 h) indicate that most sub-visible particles were already present at the start of the test. The evolution over time remained consistently low and well within USP <788> limits, suggesting that most detected particles originated from the system baseline rather than mixing activity.
- Particle levels stabilized by T = 2 h, suggesting that the initial sample taken at T = 0 (after 1 min of mixing) were collected before particles in the bulk were fully and uniformly dispersed.
- No increase in sub-visible particle counts was observed over 24 h, even under maximum mixing speed and extreme temperatures (4 °C and 40 °C), indicating no particle generation during operation.
- Visible particles showed a similar trend, but with slightly higher variability, likely due to their low overall presence.
- Overall both visible and sub-visible particle levels stayed consistently below Cytiva’s internal specifications.
Conclusions
Our evaluation of the LevMixer™ 10 L single-use mixing system showed no increase in visible or sub-visible particles during 24 h of high-speed mixing, even under extreme temperature conditions. Most particles were present at the start of the test, and levels remained stable throughout, staying well within USP <788> limits and Cytiva’s internal specifications.
These results confirm the system’s suitability for particulate-sensitive applications, including final fill, where product purity and patient safety are critical.