pumps with magnetic levitation (e.g., Puralev®, Levitronix). By use of such a
centrifugal pump, Coronel et al. demonstrated similar production yields of IAV in
orbital shaken bioreactors for both ATF and TFF systems, respectively [44].
Nevertheless, and despite of the partial cleaning of membranes by the tangential
flow, membrane fowling is common in TFF systems at HCD and during virus
production due to the accumulation of cell debris caused by cell lysis. During the
virus propagation phase, almost complete retention of virus particles in the mem-
brane was commonly observed [70]. Therefore, in particular for virus production,
material and structural properties of the hollow fiber membranes selected are critical
for efficient production. A systematic overview on different membrane materials,
and structural and physicochemical properties with respect to filter fouling and virus
harvesting is given by Nikolay et al. (2020). With new membranes/materials
available, it will certainly be worthwhile to re-evaluate this method.
Although many problems including fouling, shear stress and product retention
are not completely solved yet, simple scale-up, good reproducibility, and suitability
for various cell lines and viruses make TFF an attractive option for cell retention in
virus production.
6.6.3
ALTERNATING TANGENTIAL FLOW
First introduced in 2000 by Shevitz, the ATF systems have been since then applied in a
variety of research and industry projects [71]. The external, pressure-based ATF
system consists of a hollow fiber unit, which is positioned between the bioreactor
and a diaphragm pump. A simplified overview and description of the ATF setup is
shown in Figure 6.6. The diaphragm pump pulls and pushes the cell suspension in the
hollow-fiber unit in an alternating way. This process can be divided into two phases:
exhaust cycle and pressure cycle [19]. Active filtration occurs during the pressure
cycle. A vacuum causes the convex diaphragm to be pulled downwards into the
chamber, thereby increasing the volume of the liquid chamber and drawing cell
suspension into the filter unit. In the filter unit, tangential filtration of the cell broth
occurs. The following exhaust cycle creates the alternating nature of the ATF system
by pushing the diaphragm with pressurized air back into the liquid chamber. This
backflush transfers the filtrate back into the bioreactor without the need for an addi-
tional peristaltic pump thereby reducing the shear stress for cells. Moreover, the entire
filter length is backflushed reducing the risk of blocking of the membrane pores [72].
A peristaltic pump removes constantly the separated permeate and fresh medium
can be added directly into the bioreactor, while the cells are retained in the hollow
fiber unit. For cross-flow filtration, cake-formation (increasing thickness with in-
creasing axial distance) and tubular liquid flow profiles can occur that lead to oscil-
lating fluctuations in pressure and sporadically declining fluxes [72]. The cross-flow
velocity minimizes the tendency of membrane fouling, but even in ATF systems high
cell concentrations and long growth cycles might ultimately lead to filter clogging.
As mentioned before, the ATF system is very well-established and commercially
available. Hollow fiber units can be obtained from several suppliers. In animal cell
culture, excellent separation performance was demonstrated in HCD cultivations up
to 2E08 cells/mL, and currently most perfusion-based processes for recombinant
Process intensification
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