Very high density of Chinese hamster ovary cells in perfusion by alternating tangential flow or tangential flow filtration in WAVE bioreactor™—part II: Applications for antibody production and cryopreservation
School of Biotechnology, Cell Technology Group, KTH (Royal Institute of Technology), Stockholm, Sweden
Fed-batch mode is widely used for the production of glycoprotein. This mode is typically based on the use of concentrated feeds and stoichiometric delivery of needed components in particular amino acids.[2, 3] Often, a strategy of minimizing the by-product production is used.[4, 5] Interestingly, simulation models have shown that the cost of goods per gram of produced antibody is the same for perfusion and fed-batch.[6, 7] Lim et al. pointed out that perfusion was more favorable economically owing to a lower initial investment but that looking at the failure and contamination risk fed-batch was preferred. Systematic and experimental comparisons of production by fed-batch and perfusion are difficult to perform and can be irrelevant owing to the influence of many parameters such as the cell-specific productivity, the optimization level of the fed-batch, the perfusion length, the scale, and so forth. However, they can be used for some benchmarking: 6-, 7-, and 1.4-fold higher production in perfusion than in fed-batch for HeLa, SF-9 insect, and Chinese hamster ovary (CHO) cells, respectively, has been reported.[8-10] Fed-batch process can result in higher level of protease, lower cell viability, and higher accumulation of lactate and ammonium, whereas perfusion provides a constant environment more favorable for the health of the cells and for the quality of the product of interest. This is particularly true when a cell-specific perfusion rate is applied.[11, 12]
Cell separation by filtration has an inherent drawback, which is filter fouling. It was described for spin filter and crossflow filtration that fouling is caused by deposition of nucleic acid and dead cells.[13, 14] Filter fouling is accompanied by the retention of the product of interest inside the bioreactor. Hiller et al. installed a back-flush pump to prevent this phenomenon as they observed that up to 20% of produced antibody were retained by the hollow fiber (HF) filter cartridge in their hybridoma perfusion process. Back-flushing is systematically obtained by alternating tangential flow (ATF) system, which is described to prevent fouling16; however, this effect has not been quantified.
The concept of continuous filtration to concentrate high-molecular-weight components, that is retaining the product of interest in the bioreactor and eliminating low-molecular-weight components (e.g., toxic by-products, lactate, and ammonium) was introduced in continuous dialysis bioreactor.[17-19] The same principle is now used in industry using ultrafiltration (UF) HF perfusion, that is XD Process Technology at DSM, achieving very high cell densities; however, experimental details have not been disclosed. The advantage of this process is to retain the product of interest inside the bioreactor so that harvesting of the bioreactor is performed once instead of weekly/bi-weekly harvests of the perfused permeate. This process cannot be as long as conventional perfusion owing to the risk of degradation of the product of interest or even the risk of aggregation from high-protein concentration.
Cell cryopreservation in amounts large enough to directly inoculate a bioreactor has been described some years ago for hybridoma cells. Cryopreservation in bags is widely used for blood cell storage and has been studied for suspension of CHO and BHK cells stored from shake flask or bioreactor culture at 20 × 106 cells/mL[22, 23] or transient expression of HEK293 cells in suspension. Over the last decade, cell banking of large cell amounts, achieved by high cell density and large stored volume, has had an increasing interest in the biopharmaceutical industry. It has the obvious advantage of a gain of 2–3 weeks of time and labor compared to the classical approach of small-volume cryovials at low cell density.
This article, performed with an IgG1 producing CHO cell line, reports the results obtained together with Part I. The cell growth and associated observation of broth viscosity using microfiltration (MF) perfusion were presented in Part I for two perfusion runs using MF tangential flow filtration (TFF), TFF#6 and TFF#10, and four runs using MF ATF, ATF#5, ATF#8, ATF#9, and ATF#15A-B. Part II of this study focuses on the applications of perfusion by HF: the monoclonal antibody (MAb) production using MF ATF or MF TFF, the production obtained using the same perfusion settings with an external hollow fiber ultrafilter cartridge (UF HF), a comparison with fed-batch production, and cell bank manufacturing from high-cell-density bioreactor.
Materials and Methods
Perfusion culture processes
The experimental procedure for MF perfusion was described in Part I. The same procedure was applied for UF perfusion except for the following. The cells were continuously circulated through the lumen side of the UF HF, using a flow rate of 1.5 L/min (shear rate, 2,790 s−1). In ATF and TFF systems, the UF HFs were RTPUFP-50-C-5A (GE Healthcare) with 50 kDa pore size, 0.5 mm lumen, 520 polysulfone fibers, 30 cm nominal flow path length, and 2,000 cm2 filter area.
Fed-batch cultures in Cellbag™
The cells were inoculated in the same Cellbag™ as in perfusion process at a seeding cell density of 0.8 × 106 cells/mL in 2 L animal component-free IS CHO CD XP medium with hydrolysate (Irvine Scientific), supplemented with 2 mM glutamine (Irvine Scientific) and Streptomycin/Penicillin G/Amphotericin B (SAFC) as in perfusion process. The feeding strategy consisted in adding 225, 150, and 75 mL feed medium, 15/15%/% Efficient Feed A/B (Invitrogen) in IS CHO CD XP medium, on days 1–7, 8, and 9-end, respectively. Glucose and glutamine boost additions were performed daily according to the cell need. The set points were 35% DO, pH 7, and 37°C temperature or 37°C decreased to 35.5°C on day 7. The pH and DO were controlled as in perfusion process. The rocking rate, angle, and gas flow rate were 20–22 rpm, 5–6°, and 0.1 L/min with O2 concentration up to 30%.
Computational equations of the kinetics rates
For the fed-batch process, the apparent cell growth rate (µ), the cell-specific rates of glutamine consumption (qgln), and ammonium production (qamm) were calculated as follows:
where Cv= cell density, V = bioreactor volume, DFB = dilution rate dV/(V dt), Gln = glutamine concentration, Amm = ammonium concentration in the culture; subscripts feed, stock, and shoot refer to daily added feed medium, stock solution concentration used for shoots and daily added shot volume of stock solution; ΔT = time interval between additions (ΔT =1 day); rdegr = degradation rate of glutamine, measured to be 0.046 day−1 in IS CHO CD XP medium at 37°C by recording the degradation during 7 days. Similar equations were used for the cell-specific rates of glucose consumption (qglc), lactate production (qlac), and MAb production (qMAb) except that the degradation term was skipped.
For the perfusion process, the variable computation was presented in Part I. The MAb cell-specific productivity and the accumulated harvested MAb production (HTtot) were calculated as follows:
with MAbbrx = MAb concentration in the bioreactor, MAbHT = MAb concentration in the harvest line, D = perfusion rate, Vbleed = bleed volume, VHT = harvest volume in perfusion or fed-batch runs.
Cryopreservation and cell thaw tests
Cells were frozen either at 108 or at 0.5 × 108 cell in 1 mL vial by taking the cell broth directly from the bioreactor: the cell broth was collected with a syringe and was put immediately on ice. It was then either proceeded as such or diluted at 1:2 with fresh Ex-Cell 302 (SAFC) (Ex-Cell 302 medium was selected for this operation for two reasons: the cells could pass from IS CHO CD XP medium to Ex-Cell 302, and vice versa, without adaptation; and Ex-Cell 302 ACF medium had been used in the research cell bank and cell expansion in shake flask for historical reasons). In both cases, 10% dimethyl sulfoxide (DMSO) (SAFC) was added before vial storage at −80°C in insulated box for 1 day, followed by liquid N2 storage. The time between collecting the cell broth from the bioreactor and the storage at −80°C was ≤5 min. The cell thaw was performed in shake flasks at 106 cells/mL: a cryo-vial was thawed in 37°C water bath until <20% of iced cell could still be observed; the cells were then transferred in a shake flask and prewarmed Ex-Cell 302 with 4 mM glutamine (named “medium A” here) was added. DMSO was eliminated on day 1 by centrifugation (5 min, 100g) and resuspension in fresh medium A at 106 cells/mL. Afterward, the cells were passaged in medium A as described in Part I. The productivity test consisted in prolonging the batch cultivation in shake flask and measuring the MAb production.
Results and Discussion
Perfusion with UF HF
Two runs were performed to evaluate the perfused bioreactor using UF either mounted with ATF (ATF#18) or mounted with TFF (TFF#21). The same settings as MF HF perfusion were used except the following items: (1) the HFs were 50 kDa UF with 2,000 cm2 filter area instead of MF, (2) the recirculation flow rate was increased compared to MF HF owing to the larger filter area. The recirculation rate was the maximal flow rate possible of the ATF-2, that is 1.5 L/min. This flow resulted in shear rate of 2,790 s−1, whereas 1 L/min in MF HF resulted in shear rate of 3,400 s−1 owing to MF's smaller fiber number, 50 instead of 520. Although the shear rate was lower than using MF, the recirculation rate was higher and hence a preliminary study to deem the pumping deleterious effect on the cells was performed (see the next paragraphs).
After an exponential growth comparable in both systems, maximal cell densities of 1.27 × 108 and 1.01 × 108 cells/mL were reached in TFF#21 and ATF#18 runs, respectively, after 11 and 12 days (Figure 1a). The growth rates were comparable to those observed using MF HF with a fast exponential growth until ∼30 × 106 cells/mL followed by a slower rate (Figure 1b). On day 12, run TFF#21 suffered from erroneous control settings, leading to too high DO (∼100%) and a subsequent viability drop to 88% (data following day 12 not shown). In ATF#18 run on day 10, pCO2 reached 30 kPa, a growth inhibitory level, (Figure 1c), and hence the rocking rate and angle were increased from 22 to 26 rpm, 7° to 23–27 rpm, 7.2°, to improve CO2 removal; a higher agitation being avoided to prevent air bubble occurrence in the dip tube (Part I). Increasing the agitation, and thus the gas transfer, did not prevent pCO2 from further increasing from 30 to 34 kPa on day 11, (Figure 1c), causing interruption of cell growth. Furthermore, on day 11, the PRV exhaust decreased to −0.75 bar (or −11 psi) and the ATF motion stopped a few hours later owing to insufficient vacuum similar to that was observed using MF ATF (Part I). During the TFF perfusion, the pCO2 was kept under 16 kPa even at high cell density as the rocking rate and angle could be increased with limited risk of damage from air occurrence in the dip tube. This pCO2 level was comparable to the runs using MF HF at similar cell densities (Part I). In ATF#18 run after day 9, at cell density ≥0.8 × 108 cells/mL, the average cell diameter (ACD) significantly increased, reaching 19.2 µm on day 11 (Figure 1c). A larger cell diameter is typical for cell growth arrest. On the contrary, using the TFF system, the ACD was constant (around 17.5 µm) after day 4.
Pressure in UF HF
Contrary to the cultures using MF membrane, the permeate pressure (P2) in UF ATF run (ATF#18) and UF TFF run (TFF#21) decreased linearly with increasing cell density and perfusion rate for cell densities of >20 × 106 cells/mL (Figures 2a,c). P2 reached −0.3 to −0.4 bar at 108 cells/mL density operated at D = 5.5 RV/day. As expected, the pore size of the UF HF required stronger harvest suction than the MF HF. As shown in Figure 2b, using UF HF in TFF#21 run the inlet pressure (P1) in function of the cell density was lower but had a trend comparable to the one obtained using MF HF in TFF#10 run. As observed in Part I, a high correlation could also be observed between P1 and the cell broth viscosity, however, with a smaller proportional factor owing to the different filter, resulting in a different hydrodynamic resistance. As mentioned above, on day 12 at 1.17 × 108 cells/mL density, the viability dropped owing to elevated DO; simultaneously P1 increased to 0.47 bar. It continued to increase up to 0.8 bar the following 2 days, whereas the viability dropped to 82% and the cells did not grow anymore (data not shown). The increased P1 can probably be attributed to the low cell viability creating cell debris and DNA residue; but not to the high cell density as it had been higher, 1.27 × 108 cells/mL on day 11, whereas P1 was lower (0.26 bar).
Effect of recirculation pump on cells
In the TFF system, shear stress can be obtained from the passage in the HF or in the tubing system, for example edges, connections, and from the recirculation pump. An experiment was performed to quantify this latter effect by pumping the cell broth in the same settings as used in the TFF system but with the HF short circuited. Different recirculation rates up to 2.75 L/min were applied every day, showing no impact on the cell growth and viability, which remained ≥95% (Table 1).
Table 1. Effect on the Cell Growth and Viability of Different Recirculation Speeds by Pumping Using a Watson Marlow 620S (Two Rollers)
Pump Speed (L/min)
Viable cell density (106 cells/mL) at initial time
Viable cell density (106 cells/mL) (after time [hours])
Viability (%) at initial time
Viability (%) after 24 h
Three runs, FB#11, FB#16, and FB#22, were performed in fed-batch mode for a comparison with perfusion in the identical bioreactor. The fed-batch runs were identical except FB#16 run, which had a temperature shift (Materials and Methods section). In all the fed-batch runs, the cells had a growth with a maximal µ = 0.7 d−1, an exponential growth until days 6–7 and a maximal viable cell density of 15–18 × 106 cells/mL (Figure 3a). This cell density pattern was typical for a fed-batch culture as described in studies reported in previously published literature.[3, 27] The viability was high (≥95%) until day 11 and the mild hypothermia at 35.5°C improved the viability (≥97%). The concentrations of MAb, glucose, glutamine, lactate, and ammonium, (Figures 3b–d) were typical for a fed-batch process with MAb accumulating over time, low glucose and glutamine concentrations (except glucose from day 7 in FB#11 owing to manipulation error), low final lactate concentration and high final ammonium concentration.[28-30] The specific rates qglc and qlac were high at the beginning of the fed-batch cultures and progressively decreased with reduced cell growth as often reported for fed-batch process (Figures 4a,b).[31, 32] The qgln and qamm data were noisier but it was observed that after day 10 qamm increased (Figures 4c,d). In comparison, these rates were comparable between day 5 and the run-end during all the perfusion runs using MF or UF, ATF or TFF, except for higher qgln and lower qamm at cell density of >1.6 × 108 cells/mL (Part I).
MAb production in UF ATF and UF TFF perfusion runs
The MAb concentration in the bioreactor (MAbbrx) increased rapidly to 1,801 mg/L in ATF#18 (on day 11) and 2,978 mg/L in TFF#21 (on day 12) and at similar rate, whereas it stayed at the lower detection limit in the harvest line (Figures 5a,c). A fast MAb accumulation was expected owing to the increasing cell density and the 50-kDa membrane completely retaining the MAbs in the bioreactor.
MAb production in MF ATF and MF TFF perfusion runs
A comparable pattern was observed in all the MF perfusion runs except run ATF#8 and run TFF#10 after day 20: MAbbrx and the MAb concentration in the harvest line (MAbHT) increased rapidly during the first 6–7 days, then MAbHT stabilized around 93–158 mg/L, whereas MAbbrx stabilized around 176–243 mg/L on day 9–10, thus at a higher level than MAbHT and with a 3-day delay (Figures 5a–c). A slow MAbHT decrease and MAbbrx increase with time were even observed in some runs, for example TFF#10 on days 10–20. Run ATF#8, inoculated at 5.5 × 106 instead of 0.45 × 106 cells/mL, generated a faster MAb production with comparable MAbHT profile shifted 3 days upward. Higher MAbbrx and MAbHT were observed in ATF#8 and TFF#6 runs, probably owing to the transitory use of another medium (Materials and Methods in Part I) and to D = 1.3 RV/day instead of 1.5 RV/day in the other runs. This higher production was confirmed by computing the volumetric production (data not shown), and qMAb (see below). Notice that MAbbrx above 400 mg/L on day 11 in ATF#15A-B was owing to the interruption of ATF function (Part I) and should not be taken into account here.
MAbHT and MAbbrx stabilization is typical for perfusion run at different cell densities using constant CSPR,[11, 12] as applied here: a larger MAb amount produced by a higher cell density is more diluted when using a higher perfusion rate. In case of complete MAb transfer from the bioreactor to the harvest, MAbHT and MAbbrx are identical; however, they were different here owing to a partial MAb retention by the HF. Furthermore, the concurrent slow MAbbrx increase and MAbHT decrease were owing to a MAb retention increasing with time, for example in TFF#10 run, the 1st HF lasted 30 days, during which time filter fouling increased.
Interestingly, a transitory period of higher MAbHT was observed immediately subsequent to a significant increase of the perfusion rate on day 21 in TFF#10 run. This was followed by a transitory down slope. It is probable that the sudden change of the flow rate through the MF HF pores temporarily removed the cake fouling the membrane; however, it reformed after a few days as can be seen from MAbHT decrease. This observation is in agreement with the use of back flush to prevent fouling as in the ATF operation or HF TFF back-flush pumping. After day 20, MAbHT was ≈154 mg/L and MAbbrx became ≥1,000 mg/L with a slight continuous increase with time, indicating an important MAb retention. MAbHT profile showed several peaks, which were approximately mirrored by reversed variations in MAbbrx, probably subsequently to transitory property changes of the fouled HF. On day 41 and onward, the perfusion rate was increased again. However, this time, MAbHT stayed stable, whereas MAbbrx increased highly and correlated with the cell density increase. At this stage, the HF was probably irreversibly fouled so that the cake could not be removed as observed day 21. In agreement with this, irreversible cake formation of this HF was confirmed 8 days later, that is after run completion, following the method described by Russotti et al. (data not shown).
The accumulated harvested MAb production, one of the most important parameters for the process, is shown in Figure 6a. In the MF runs stabilized at ∼25 × 106 cells/mL cell density (ATF#5, ATF#8, ATF#9, TFF#6, and TFF#10 until day 20), the slope of HTtot was comparable. This was also true for ATF#8 run in which MAb accumulated earlier owing to the higher initial cell density. Higher cell densities resulted in steeper slope (ATF#15A-B or TFF#10 from day 20). In Figure 6b, HTtot in run TFF#10 is shown together with the total accumulated MAb amount really produced by the cells, MAbtot
MAbtot was higher than HTtot by a difference, sum of the MAb loss in the cell bleeds and another smaller loss from the residual MAb left in the bioreactor at the run completion. An illustration is summarized in Table 2 where MAb loss in bleeds and residual in bioreactor are presented for ATF #9 and TFF#10 runs for more than 17 days with a cell density maintained at 25 × 106 cells/mL.
Table 2. MAb Loss in ATF#9 and TFF#10 for More Than 17 days With Cell Densities Maintained at 25 × 106 cells/mL
Loss of MAb in Bleeds
Loss of residual MAb in Bioreactor
Cellular Production MAbtot
Analysis of the Yields
The concentration yield (Yconc), ratio MAbHT/MAbbrx, was 100% during the first days and then decreased rapidly with time, reflecting the partial retention (Figure 7a). After the first days, the production yield (Yprod), ratio HTtot/MAbtot, became significantly higher than Yconc as expected owing to its integral character: for instance, in MF ATF#15A-B performed without bleeds, Yconc decreased to 50% or less after 10 days, whereas Yprod increased to 86–92% (Figure 7b). In the runs stabilized at 25 × 106 cells/mL density, Yprod was between 54 and 71% and between 46 and 56% when using ATF and TFF, respectively, after the first days. It was concluded that there was a MAb retention using both systems but using TFF caused a larger retention and hence the ATF system was more favorable for the MAb production than the TFF system. This has been described theoretically16; however, to our knowledge, this is the first time that data are published. The yield difference was higher in the case of production at stable cell density with cell bleeds as larger amounts of MAbs were discarded. Another drawback of MAb retention by the HF is an increase of the MAb residence time inside the bioreactor, which is, of course, an issue for sensitive glycoproteins.
Yconc decreased with time and with increasing cell density, probably owing to a higher amount of cell debris and nucleic acid in a similar way as reported for the filter fouling in spin filter. The debris and nucleic acids were not eliminated from the bioreactor except in the cell bleeds.
Effect of Shear Rate
Recirculation rates of 0.3–1 L/min, that is shear rate of 1,000–3,400 s−1, were applied (Table 1 in Part I). Increasing the recirculation rate did not improved Yconc, for example TFF#10 run had slightly lower yield than TFF#6 run on days 9–19 for recirculation rates 1 and 0.3 L/min, respectively (Figure 7b). These shear rates were probably not high enough to observe a favorable effect from increasing the shear rate as in yeast MF harvest for shear rates of ≥8,740 s−1.33 However, a higher recirculation rate was more favorable for ATF function, that is for reduced air occurrence in the dip tube (Part I).
Comparison of MAb production in perfusion using MF or UF HF and fed-batch
Figure 6a shows HTtot for the different runs performed at different cell densities and in the absence or presence of bleeds. Runs UF ATF#18, UF TFF#21, and MF ATF#15A-B resulted in comparable HTtot. As discussed above, the cell bleeds caused a lower production for MF TFF compared to MF ATF. The MAb production obtained in the fed-batch runs was at the lower edge of the perfusion runs. MAb harvested after 12 days in UF and MF, ATF, and TFF perfusion runs as well as fed-batch were compared based on data in the absence of cell bleed for UF ATF#18, UF TFF#21, MF ATF#15B, MF TFF#10 (for which a calculation was made based on the real data) and average of FB#11, FB#16, and FB#22: the harvested MAb production was comparable and ∼12 g for all the perfusion runs and was 2 g in fed-batch cultures, that is six times lower than in perfusion. Yuk et al. reported a sevenfold higher titer of recombinant oncolytic adenoviral vector in perfusion using ATF compared to fed-batch in an infection process of HeLa. Jardin et al. obtained a production of Secreted Alkaline Phosphatase eightfold higher in perfusion using acoustic settler than in fed-batch mode in an SF-9-BEV insect cell culture. Meuwly et al. converted a CHO perfusion process into fed-batch. The productivity per bioreactor unit volume and year was ≈70% in fed-batch compared to perfusion in packed-bed bioreactor.
Illustrating the potential MAb production in the perfusion system used here, in run TFF#10, a total of 93 g of MAb was harvested after 47 days although this run was a study run with periods at cell density maintained at 25 × 106 cells/mL and 1.1 × 108 cells /mL before reaching 2 × 108 cells/mL. Furthermore, it was calculated from the data of this run that 34 g could be harvested over a 17-day period of culture including cell expansion followed by cell density maintained at 108 cells/mL and that 22 g was harvested per week while maintaining the cell density at 108 cells/mL. In other words, a 1-month culture would generate 57 g MAb in this 4 L working volume process using this model cell line with moderate cell-specific productivity in view of today's industrial standard. The comparison of perfusion and fed-batch is, of course, very difficult to make as it depends on the cell density and the perfusion culture length but other factors such as the scalability and the total cost of goods covering upstream and downstream processes should also be taken into account.
qMAb was comparable in all the ATF and TFF runs, ∼9 pg/cell/day, except ATF#8 and TFF#6 runs partly performed with another medium, ∼13 pg/cell/day (Figure 7c). It also seems that qMAb decreased somewhat in TFF#10 run from day 42 at a density of ≥1.31 × 108 cells/mL. This could potentially be attributed to the high cell density as the cell line was stable as shown by a productivity test performed from cells frozen at 2 × 108 cells/mL on day 44 (data not shown). qMAb in fed-batch was in average comparable or lower than in the perfusion runs.
Cell banking and seed expansion
Cells taken from ATF#15B run at 108 cells/mL cell density on day 12 (i.e., day 30 of the whole ATF#15A-B run) were cryopreserved in 1-mL vials. The cells were frozen at cell concentrations of 108 and 0.5 × 108 cells/mL, either by adding 10% DMSO to the cell broth or by diluting with fresh medium before adding 10% DMSO. The cell resuscitation and subsequent growth were excellent with viability in average 90–91% on day 1 and higher after this day and cell growth already observed from day 1 or 2 (Figures 8a,b). Duplicate productivity tests were performed from one of the cell thaw cultures at passages 7 and 8 as well as a productivity test at passage 8 with supplementary addition of 200 nM methotrexate (MTX) (Figure 8c). After 1 week, average MAb concentrations and cell-specific MAb productivity of 138 mg/L and 7.1 pg/cell/day, respectively, were reached as typical for productivity test with this cell line. No effect of MTX addition was observed, indicating as well that the cells were stable and that no cell subpopulation insensitive to MTX had emerged during the 30 days of ATF#15A-B total culture period.
This study clearly demonstrates that CHO cell cryopreservation from a perfusion culture at high cell densities around 108 cells/mL is feasible, allowing high cell number with high cell growth and viability at thaw. Ninomiya et al. reported high cell density freezing at 1.5 × 108 cells/mL for hybridoma cells in the presence of 20% serum, whereas this study was performed without serum. Tao et al. developed a CHO cell bank manufacturing process in which the cells were expanded up to a cell density of 27 × 106 cells/mL in a wave-induced bioreactor perfused with an interior filter separation device. They increased the final cell density of their cell bank at 0.9–1 × 108 cells/mL by centrifugation. It is probable that a controlled bioreactor environment instead of shake flask expansion is more beneficial for the cell health, the reproducibility, and reliability of the cryopreservation process.
Applications of high-cell-density perfusion process of MAb producing CHO cells in disposable WAVE Bioreactor™ using TFF or ATF were studied here using MF or UF. Cell densities higher than 108 cells/mL were obtained using UF TFF or UF ATF. Comparable amounts of MAb were produced by the cells in perfusion by ATF or TFF, MF or UF; however, the MAbs were partially retained by the MF. The retention was higher using the TFF than the ATF system. The main MAb loss caused by this retention was product discarded from the bioreactor in the daily bleeds to maintain a constant cell density. The MF TFF was thus less favorable for the production of MAb in comparison with MF ATF. From this point of view, the UF TFF and UF ATF had a major advantage compared with the MF HF as these were aimed at retaining completely the product. They also allowed a reduction of the MAb dilution, harvest from the bioreactor culture, 4 L, instead of from the accumulated harvests (≈100 L in the present cases). As expected, the perfusion process generated a higher MAb production than the fed-batch by a factor of 6 after 12 days and a factor of 28 in a 1-month perfusion at a constant cell density of 108 cells/mL. Together with Part I, our study showed that perfusion up to 1.3 × 108 cells/mL had no influence on the cell metabolism and MAb production when applying a constant cell-specific perfusion rate. The equipment, that is the WAVE Bioreactor™, the ATF and the TFF, was robust. The operational experience from this study indicated no difference concerning the HF capacity using ATF or TFF. Recirculation rates of 1 L/min (shear rate, 3,400 s−1) using MF HF and 1.5 L/min (2,790 s−1) using UF HF were well tolerated by CHO cells using ATF or TFF systems. The effect of pumping by the TFF system in the absence of HF was studied. It indicated that the pumping used in the present perfusion setting had no detrimental effect on the cells. Cell cryopreservation from high-cell-density bioreactor culture was very successful. This system was more reliable and robust for cell bank manufacturing than the classical approach of shake flask expansion as the cells were manufactured in a controlled bioreactor in the presence of a stable environment generated by the perfusion.
GE Healthcare financed this study. Many thanks to Christian Kaisermayer and Craig Robinson (GE Healthcare), The Swedish Governmental Agency for Innovation Systems (VINNOVA), for supporting the lab activities, IMED (Sweden) for giving permission to use their research cell line and Refine Technology (USA) for inputs.