Centrifugal elutriation (counterstreaming centrifugation) of cells

Lindahl first described the separation of cells by velocity sedimentation utilizing a special technique (counterstreaming centrifugation) that was later modified slightly and renamed centrifugal elutriation. Centrifugal elutriation has been applied, with variable degrees of success, to the separation of hemopoietic cells, mouse tumor cells, testicular cells, and a variety of other specialized cells as well as cells in particular phases of the cell cycle. The capacity of the elutriator to separate large numbers of cells is its chief advantage. The purities of the separated cells have not been compared with the purities of cells separated by other methods in most cases; such comparisons would permit more sophisticated comparison of elutriation with other techniques for velocity sedimentation.     

Theory and practice of centrifugal elutriation (CE). Factors influencing the separation of human blood cells

Centrifugal elutriation (CE) is currently a widely used preparative cell separation technique. In order to optimize the separation of cells that show only small differences in sedimentation velocity, several conditions that might influence the resolution capacity, such as rotor speed, counterflow, jetstream, cell load, density, and viscosity of the elutriation medium, were analyzed. Experiments carried out with human red blood cells (rbc) indicated that selective losses of rbc from the rotor caused by the jetstream, could be prevented if the separations were carried out at high rotor speeds, as predicted by the theory. In addition, high cell loads (5 X 10(8) rbc) resulted in better separations than low cell loads (5 X 10(7) rbc). Human monocytes were separated into subpopulations that differed only about 0.003 g/mL in density, but have virtually the same size. The separation was carried out either by increasing the density or viscosity of the elutriation medium or by decreasing the rotor speed. In all cases similar results were obtained. These results indicated that under optimal conditions CE can be applied for the separation of cells that differ only slightly in sedimentation velocity.     

Theory and practice of centrifugal elutriation (CE)

Centrifugal elutriation (CE) is currently a widely used preparative cell separation technique. In order to optimize the separation of cells that show only small differences in sedimentation velocity, several conditions that might influence the resolution capacity, such as rotor speed, counterflow, jetstream, cell load, density, and viscosity of the elutriation medium, were analyzed. Experiments carried out with human red blood cells (rbc) indicated that aselective losses of rbc from the rotor caused by the jetstream, could be prevented if the separations were carried out at high rotor speeds, as predicted by the theory. In addition, high cell loads (5×10⁸ rbc) resulted in better separations than low cell loads (5×10⁷ rbc). Human monocytes were separated into subpopulations that differed only about 0.003 g/mL in density, but have virtually the same size. The separation was carried out either by increasing the density or viscosity of the elutriation medium or by decreasing the rotor speed. In all cases similar results were obtained. These results indicated that under optimal conditions CE can be applied for the separation of cells that differ only slightly in sedimentation velocity.     

Zonal unit-gravity elutriation. A new technique for separating large cells and multicellular complexes from cell suspensions

A new and simple technique, zonal unit-gravity elutriation, has been devised for separating very large cells, multicellular complexes, or small organisms from suspensions consisting mainly of small cells. The separation vessel is a conical chamber with an entrance at the lower, narrower part of the cone and an exit at the upper, wider part of the cone via a dome-shaped lid. A baffle at the entrance prevents turbulence from incoming fluid. Chambers of differing widths and wall slopes are chosen depending on the sedimentation rate of the particles to be separated. A small volume of the cell suspension is placed in the chamber on the bench in a cold-room. Medium stabilized by a shallow density gradient is pumped into the base of the chamber and ascends, creating a decreasing velocity gradient. Cells sediment at unit-gravity against this ascending counterstream, and are separated into bands according to sedimentation velocity. By adjusting the flow rate of the medium, different sizes of cells can be separated. Tumor cells can be enriched, and larger blast cells can be separated from small cells in lymphoid cell suspensions. The procedure produces complete separation of thymic nurse cells (epithelial-lymphoid complexes) from free thymocytes in digested thymus suspensions and produces substantial enrichment of thymic rosettes (macrophage-lymphoid complexes). A very favorable situation for applying this technique is the isolation of Taenia taeniaformis larvae, which can be completely purified from infected liver suspensions, representing a 4 X 10(5)-fold enrichment of the parasites, with high recovery, in a single 30 min operation.     

Zonal unit-gravity elutriation

A new and simple technique, zonal unit-gravity elutriation, has been devised for separating very large cells, multicellular complexes, or small organisms from suspensions consisting mainly of small cells. The separation vessel is a conical chamber with an entrance at the lower, narrower part of the cone and an exit at the upper, wider part of the cone via a dome-shaped lid. A baffle at the entrance prevents turbulence from incoming fluid. Chambers of differing widths and wall slopes are chosen depending on the sedimentation rate of the particles to be separated. A small volume of the cell suspension is placed in the chamber on the bench in a cold-room. Medium stabilized by a shallow density gradient is pumped into the base of the chamber and ascends, creating a decreasing velocity gradient. Cells sediment at unit-gravity against this ascending counterstream, and are separated into bands according to sedimentation velocity. By adjusting the flow rate of the medium, different sizes of cells can be separated. Tumor cells can be enriched, and larger blast cells can be separated from small cells in lymphoid cell suspensions. The procedure produces complete separation of thymic nurse cells (epithelial-lymphoid complexes) from free thymocytes in digested thymus suspensions and produces substantial enrichment of thymic rosettes (macrophage-lymphoid complexes). A very favorable situation for applying this technique is the isolation ofTaenia taeniaformis larvae, which can be completely purified from infected liver suspensions, representing a 4×10⁵-fold enrichment of the parasites, with high recovery, in a single 30 min operation.     

Characterization of the efficiency of a cell separation process by the extent of elimination of a contaminating cell type

A stepwise approach to the selection of an appropriate technique for a cell separation problem is presented in which the preparative purification of cells is linked to their analytical separation. We have introduced the extent of elimination of a contaminating cell type from the cell type which one chooses to purify, as a separation parameter that characterizes the efficiency of a separation process independently of the relative cell composition of the starting material. In order to compare different separation techniques, a preparative fraction boundary needs to be chosen between the cell types. We defined this boundary in terms of the physical property on which the separation is based such that yield and purity of the isolated cell suspension are optimized simultaneously. With this analytical approach, it was found that a similar elutriation technique separated human and equine mononuclear cells equally well and that the separability of human monocytes and lymphocytes improved when the cells were separated by increasing the limiting sedimentation coefficient value of the elutriation chamber in small increments.     

Centrifugal elutriation: separation of spermatogenic cells on the basis of sedimentation velocity.

Various types of cells from the testes of mice and hamsters were separated according to differences in sedimentation velocity by centrifugal elutriation, a counterflow centrifugation technique. Approximately 3 times 10(8) cells, prepared from six mouse testes or from one hanster testis, were separated into 11 fractions in less than two hours as compared to the 4--5 hours required for sedimentation at unit gravity ("Staput"). Fractions enriched in elongated spermatids and spermatozoa (100%), stages 1--8 spermatids (69%) and pachytene spermatocytes (58%) were obtained from mouse testis dispersions. Similarly enriched fractions were obtained from hamster cells. A single fraction enriched in stages 1--8 spermatids (mouse) was prepared in less than 30 minutes. As many as 2 times 10(9) cells were separated in a single procedure. Spermatogenic cells exhibited no evidence of structural damage with trypan blud and phase microscopy, and recovery was essentially 100%. Centrifugal elutriation had no effect on sperm motility or on the plating efficiency of CHO cells.     

Separation and concentration of phytoplankton populations using centrifugal elutriation

Centrifugal elutriation is a technique for separating particles on the basis of their sedimentation velocity, an expression of size, shape, and specific gravity. Unialgal cultures, mixtures of two phytoplankton cultures, and natural seawater samples were elutriated to determine the feasibility of this technique for collecting fractions of different cell cycle phases, separating two phytoplankton species, and concentrating cells from dilute samples. Elutriation resulted in the separation of a culture of Dunaliella tertiolecta and Phaeodactylum tricornutum into homogeneous fractions of each species. Cells in the natural seawater sample were concentrated by nearly 2 orders of magnitude. Centrifugal elutriation provides an alternative cell separation and concentration technique when large numbers of cells are required.     

Cell cycle synchronization of animal cells and nuclei by centrifugal elutriation

Synchronization of cells and nuclei is a powerful technique for the exact study of regulatory mechanisms and for understanding cell cycle events. Counterflow centrifugal elutriation is a biophysical cell separation technique in which cell size and sedimentation density differences of living cells are exploited to isolate subpopulations in various stages of cell cycle. Here, a protocol is described for the separation of phase-enriched subpopulations from exponentially growing Chinese hamster ovary cells at high-resolution power of elutriation. The efficiency of elutriation is confirmed by measuring the DNA content fluorimetrically and by flow cytometry. The resolution power of elutriation is demonstrated by the ability to fractionate nuclei of murine pre-B cells. The installation and elutriation by collecting 16-30 synchronized fractions, including particle size analysis, can be achieved in 4-5 h.     

Separation of hepatocytes from suspensions of mouse liver cells using programmed gradient sedimentation in gradients of ficoll in tissue sulture medium

Liver cells were obtained in suspension using a solution of lysozyme in Joklik's modification of minimum essential medium. Hepatocytes were separated in 74.2 ± 12.9% purity from other liver cells having different densities using isopycnic centrifugation, in 97.1 ± 1.9% purity from other liver cells having different diameters using velocity or rate-zonal centrifugation. A previously reported computer integration of the differential sedimentation equation was employed in determining the gradient design and the speed and duration of centrifugation which would permit purification of hepatocytes from other liver cells. More than 98% of the hepatocytes separated by velocity sedimentation excluded trypan blue. Velocity sedimentation is superior to isopycnic centrifugation for the separation of hepatocytes from liver cell suspensions because it gives more highly purified hepatocytes and because it requires lower centrifugal forces for shorter periods of time.     

Cell-cycle differences of HL-60 leukemia cells fractionated by centrifugal elutriation

HL-60 leukemia cells were fractionated into G1 and S/G2 populations using a rapid centrifugal elutriation technique, and studied for differences between the cell-cycle phases. The G1 fraction was found to contain smaller cells with a sedimentation velocity of 7 mm/h. The S/G2 fraction consisted of larger cells with a sedimentation velocity of 125 mm/h. The latter fraction was found to have a peak level of the enzyme (2'-5')An-binding protein, as compared to the G1 fraction, indicating a possible role for (2'-5')An-binding protein and its products in the growth regulation of these leukemic cells. In addition, cytofluorometric analysis of fractionated HL-60 cells indicates that elutriation is an effective fractionation method, rapidly yielding large numbers of cells for study, without the use of chemical treatments.     

Separation of Kupffer and endothelial cells of the rat liver by centrifugal elutriation

Isolated non-parenchymal cells from rat liver were separated by centrifugal elutriation into two fractions consisting of structurally intact Kupffer and endothelial cells with purities of 91 and 95%, respectively. Purified Kupffer and endothelial cells showed nearly equal specific activities for the lysosomal enzyme acid phosphatase, whereas the specific activity of cathepsin D was about 3 times higher in Kupffer cells. It was calculated that a significant amount of the cathepsin D activity in the liver is present in the Kupffer cells.     

Characterization of a CV-1 cell cycle. V. An assessment of velocity sedimentation for cell separation and synchrony.

Velocity sedimentation at unit gravity has been used to enrich populations of logarithmically growing cells in different cell cycle phases. In order to evaluate the degree of synchrony obtained by this method of cell separation, synchronous populations of CV-1 cells, initially obtained by the selective detachment of mitotic cells from roller cultures, were separated by velocity sedimentation. It was found that although the mean cell volume increased linearly, the cells remained heterogeneous with respect to size during all phases of the cell cycle. Since the velocity sedimentation technique depends upon discrimination of cell size, the size heterogeneity of cells throughout the cycle limits the degree of synchrony which can be obtained by this method.     

THE RESOLUTION OF MIXTURES OF VIABLE MAMMALIAN CELLS INTO HOMOGENEOUS FRACTIONS BY ZONAL CENTRIFUGATION

Large-scale separation of mixtures of mammalian cells was obtained with the A-1X zonal centrifuge rotor and density gradients consisting of Ficoll dissolved in modified Eagle's MEM suspension-culture medium. The cells remained viable as tested by plating efficiency or by motility observed with time-lapse photography. Rabbit thymocyte and HeLa cell mixtures were separated with 99 and 89 per cent purity, respectively. Mixtures of thymocytes and suspension-cultured, human acute leukemia cells (Roswell Park strain LKID) were separated with 93 and 91% purity, respectively. HeLa cells were isolated 92% pure from a mixture with horse leukocytes. A book of charts giving the sedimentation position and velocity versus time of cells in the A rotor under standard conditions of gradient composition, angular velocity, and temperature was prepared with the use of a computer program based on the differential sedimentation equation. The charts are used to estimate the centrifugation time necessary for maximum separation of cells. The success achieved in separating mixtures of cells points to the future possibility of large-scale fractionation of solid tissues, especially tumor tissues, into preparations cf viable cells of a single type.     

Separation of ram spermatids by sedimentation at unit gravity

Suspensions of 1 × 10⁸ ram testis cells were prepared with trypsin and separated by velocity sedimentation at unit gravity in a non-linear Ficoll gradient. An improvement was made in the technique of cell suspension preparation to increase the viability of heat-sensitive germ cells. Six bands of cells numbered from I–VI were characterized by their sedimentation velocity and modal cell volume. The distribution of various classes of germ cells in these bands, and especially spermatids at different maturation stages, was determined using histological techniques and confirmed by kinetic profiles and autoradiographic analyses of ³H-thymidine incorporation. A homogenous population of round spermatids (93–96%) was obtained in the high sedimentation velocity part of band IV. Although elongated spermatid separation does not rigorously follow the maturation stage, it gives populations which can be used for the investigation of biochemical changes during spermiogenesis. Taking into account the viability and the ultrastructure of germ cells after separation, it was shown that the use of Ficoll as a gradient material instead of bovine serum albumin causes cellular damage. We successfully applied the technique of velocity sedimentation to testis cell separation in the bull, boar, billy-goat and stallion.     

Human lung mast cells: purification and characterization

Detailed studies of the biochemistry and pharmacology of mast cell-mediated inflammatory disorders have been hampered by the inability to purify human mast cells. We now report techniques to purify human lung mast cells to apparent homogeneity. The major purification steps are: 1) dispersion of lung fragments into a single-cell suspension with enzyme combinations (pronase-chymopapain, collagenase-elastase); 2) partial purification by countercurrent centrifugation elutriation (CCE); and 3) affinity column chromatography. Enzymatic dispersion yielded suspensions with congruent to 10(6) mast cells per gram of lung parenchyma in purities of 1.2 to 9.7%. Dispersed mast cells responded comparably to those in parent lung fragments to challenge with anti-human IgG and pharmacologic agonists. Elutriation of lung cell suspensions yielded mast cell-enriched fractions with purities up to 70%. High purity mast cell fractions were combined, passively sensitized with purified human penicillin (BPO)-specific IgE, and purified by a BPO-affinity column chromatography procedure. Post elutriation mast cell purities of 29 +/- 3.5% were increased to 84 +/- 3% (range 65 to 98%) by the affinity column. Short-term (24 hr) culture of column-purified mast cells allowed adherence of non-mast cell contaminants to tissue culture plates, further increasing purity (up to 100%). Purified mast cells were intact and functional as assessed by dye exclusion, survival in short-term culture, IgE-mediated histamine release, and modulation of release by the pharmacologic agonists adenosine, IBMX, prostaglandin E2, and fenoterol.     

Reverse banding of Japanese quail microchromosomes.

Cells isolated from adult and fetal rat liver and ascites hepatoma were separated into distinct populations by velocity sedimentation at unit gravity. Normal adult liver ceils sediment with modal velocities ranging from 5 to 50 mm/h. Volume analysis using a Coulter-type counter demonstrated that the separation was based primarily on cell size. Appreciable differences were observed in the sedimentation velocity distribution of cells isolated from different normal lobes or regenerating liver. Most fetal rat liver cells sediment with velocities inferior to 12 mm/h. Ascites (Novikoff) hepatoma cells present a velocity distribution more similar to that of fetal than to normal adult liver cells. The results are discussed in terms of cell-size changes associated with liver maturation, regeneration or transformation.     

Analysis of MOPC-315 plasmacytoma by elutriation and flow cytometry

Intravenously transplanted murine plasmacytoma MOPC-315 cells were separated from normal spleen cells from a tumour-bearing mouse by elutriation and characterized according to morphology, immunologic properties and clonogenicity. Morphologically, both lymphocytoid and plasmacytoid cells were separable by elutriation. Flow cytometry correlated DNA content and intracytoplasmic IgA content and demonstrated two distinct populations, both in cell cycle, but with markedly different cellular IgA levels. Density gradient separation characterized the lower-density cells with lower IgA content and higher clonogenicity. From these studies a model of cellular differentiation is proposed.     

Characterization of rat bone marrow lymphoid cells. I. A study of the distribution parameters of sedimentation velocity, volume and electrophoretic mobility

Various cell populations in rat bone marrow were characterized by means of a two dimensional separation using velocity sedimentation and free flow electrophoresis and by electrical sizing of the separated cells. Up to 4.5 mm/hr five different populations with discrete distributions in volume (coefficient of variation 10% to 13%) and sedimentation velocity (coefficient of variation 6% to 10%) were observed. Three of the small sized populations represented lymphocytes and small normoblasts and two of the larger sized populations represented myeloid cells. Almost all of these cells were in the G0/G1 cycle phase. In the faster sedimenting fractions which contained immature myeloid, erythroid and undefined blast cells and two S phase populations, discrete volume distributions were not evaluated. The cell populations with homogeneous volume (particularly the small lymphocytes) showed high density variations which condiserably impair the separation resolution. The cells sedimenting slower than 3.5 mm/hr were further separated by means of free flow electrophoresis into three peaks differing in electrophoretic mobility (EPM). The peaks of low and high EPM contained two populations and the peak of medium EPM contained three populations all characterized by normal volume distributions of uniform coefficient of variation between 11% and 14%. The small cells in the peaks of high and medium EPM were normolblasts and the other cells were lymphocytes. The biological significance of these results is discussed.     

Isolation and characterization of cell cycle-enriched subpopulations of a murine macrophage cell line by centrifugal elutriation

The cell cycle of the P388D 1 murine macrophage line was delineated and suspensions of exponentially growing cells were separated by centrifugal elutriation into subpopulations enriched in the various phases of the cycle. Analysis of both growth and labelled mitoses curves disclosed that the doubling and cell-cycle times were essentially identical (18.4 and 18.3 h), indicating that all cells were in cycle. In addition, G1 + 1/2M was 4.3 h, whereas S phase and G2 + 1/2M lasted about 12 and 1.5 h. The most homogeneous subpopulations of phase-enriched cells obtained by elutriation were cells in G1 and S, where purities (estimated by both labelling indices and analyses of DNA histograms obtained by flow cytometry) exceeded 80%. Isolation of G2 + M-phase cells was not as efficient, although the purity of these subpopulations was consistently greater than of 50%, an approx. 10-fold enrichment over unseparated suspensions of cells. Comparison of IgG2a-Fc-receptor-mediated phagocytic activities among the phase-enriched subpopulations showed that cells in G2 had appreciably enhanced activity.