Deformation of human erythrocytes in a centrifugal field.

A new method for altering red cell morphology by high-speed centrifugation of cells through a physiological medium is described. Cell shape is preserved for microscopic analysis by allowing the sedimenting cells to pass from the physiological medium into a glutaraldehyde fixative solution. Examination of the deformed, fixed cells indicates that the vast majority resemble spheres with a flat, triangular tail. Measurements of the overall length of deformed cells show a nearly linear relationship between cell length and centrifugal force; average cell length increased from 8 to 11 micrometer as the centrifugal field was increased from 2,000 to 15,000 g. These data suggest that this centrifugal technique may be useful for evaluating cellular deformability and, potentially, the material properties of red cells.     

Centrifugal assessment of cell adhesion

The design of a chamber for determining the centrifugal force necessary to detach cells from various substrates is presented. Cells from an SV40-transformed murine peritoneal macrophage line and human erythrocytes were used to assess the feasibility of using the chamber for studies of cell adhesion. This work was confirmed the usefulness of the chamber and provided data concerning the force necessary to detach the cells. These data indicated that the percentage of cells detached from a glass substrate was not a function of force alone. The number of cells detaching increased with the impulse applied to the cells when they were exposed to a constant force. Similarly, when the impulse applied to the IC21 cells was maintained at a constant level, the percentage of cells detached by a centrifugal force increased with the magnitude of the force.     

Kinesin force generation measured using a centrifuge microscope sperm-gliding motility assay.

To measure force generation and characterize the relationship between force and velocity in kinesin-driven motility we have developed a centrifuge microscope sperm-gliding motility assay. The average (extrapolated) value of maximum isometric force at low kinesin density was 0.90 +/- 0.14 pN. Furthermore, in the experiments at low kinesin density, sperm pulled off before stall at forces between 0.40 and 0.75 pN. To further characterize our kinesin-demembranated sperm assay we estimated maximum isometric force using a laser trap-based assay. At low kinesin density, 4.34 +/- 1.5 pN was the maximum force. Using values of axoneme stiffness available from other studies, we concluded that, in our centrifuge microscope-based assay, a sperm axoneme functions as a lever arm, magnifying the centrifugal force and leading to pull-off before stall. In addition, drag of the distal portion of the axoneme is increased by the centrifugal force (because the axoneme is rotated into closer proximity to the glass surface) and represents an additional force that the kinesin motor must overcome.     

Limited use of Centritech Lab II Centrifuge in perfusion culture of rCHO cells for the production of recombinant antibody

Perfusion cultures of recombinant Chinese hamster ovary cells, producing recombinant antibody against the S surface antigen of Hepatitis B virus, were carried out in continuous and intermittent mode using a Centritech Lab II Centrifuge. In the continuous perfusion process, despite the absence of shear stress from the pump head, long-term operation was not possible because of continuously repeated exposure to oxygen limitation and low temperature, as well as shear stress from centrifugal force. In the intermittent perfusion processes, the frequency of cell-passage through the centrifuge was substantially reduced, compared with the continuous perfusion mode; however, the degree of reduction could not guarantee stable long-term operation. Although various operating parameters were applied in the intermittent perfusion cultures, high cell densities could not be maintained stably. In a single bioreactor culture system, a specific cell that is returned from the centrifuge to the bioreactor could be transferred from the bioreactor to the centrifuge again in the next cycle. These repetitive damages, caused by shear stress from the pump head and centrifugal force, as well as exposure to suboptimal conditions such as oxygen limitation and low temperature below 37 degrees C, were more serious at higher perfusion rates. Subsequently, damaged cells and dead cells were continuously accumulated in the bioreactor. Culture temperature shift from 37 to 33 degrees C increased antibody concentrations but showed inhibitory effects on cell growth. The negative effects of lowering culture temperature on cell growth overwhelmed the positive effects on antibody production. To protect cells from shear stress, Pluronic F-68 was 2-fold concentrated in the culture medium; nevertheless, a significantly higher concentration of Pluronic F-68 (2 g/L) may have inhibitory effects on cell growth.     

High density culture of hybridoma cells using a perfusion culture vessel with an external centrifuge

The influence of centrifugal force on the growth of cells was examined by exposing the cells of the mouse-human hybridoma X87 line to centrifugal force (100–500 G) for ten minutes twice a day and comparing the static culture with that of unexposed cells. In this experiment, both cell proliferation and specific antibody productivity were independent of the centrifugal effect, and gave the same results as in the case of no exposure to centrifugal force. High density cultivation of the mouse-human hybridoma X87 line was obtained by a perfusion system where the cells were separated from the culture medium by continuous centrifugation. In the serum-free culture, the maximum viable cell density exceeded 10⁷ cells/ml, and monoclonal antibody was stably produced for 37 days. The results in this culture were equivalent to those obtained by intermittent centrifugal cell separation from the culture medium, and separation by gravitational settlement.     

一种新的体外细胞牵张刺激装置

体外细胞机械刺激装置是研究细胞对机械牵张反应的一种研究设备。目前此类装置有多种,但是这些装置都存在一些不便之处。本文以商品化的Flexercell Strain Unit刺激装置为参照,设计一套离心力牵张装置。通过使贴壁细胞生长的培养板以一定的速度旋转,从而使心肌细胞受到固定大小的离心力的牵张作用。酶解分离3～5d SD大鼠心肌细胞,并分别给予12和24h机械刺激:传统的20%牵张刺激和180r/min的离心力刺激。以~3H-亮氨酸掺入量反映细胞的肥大指标,并测定牵张引起的血管紧张素Ⅱ的自分泌。同对照组相比,~3H-亮氨酸掺入在离心力牵张组显著升高[(1295.17±51.19)vs(1122.67± 51.63)in 12h;(1447.5±35.96)vs(1210.67±90.92)in 24h,P<0.05]。AngⅡ在离心力牵张组均比同期末牵张组均明显升高,12h为128%(P<0.05)和24h为139%(P<0.01)。经24h的牵张,培养液中乳酸脱氢酶活性在膜牵张组显著高于离心力牵张组[(14.5±8.7)U/Lvs (7.8±4.3)U/L,P<0.05]。新型改进的机械牵张装置能够有效刺激心肌细胞蛋白合成增加和AngⅡ的分泌增加,与FlexercellStrain Unit相比,离心力牵张装置对细胞的损害较轻微。     

Standardization of Human Diploid Fibroblast Cultivation: Centrifugation Procedure

The effect of varying centrifugal forces on the growth rate, longevity, and adsorption on glass of human embryonic diploid lung fibroblasts was studied. Cells centrifuged at 120, 500, or 1,500 × g at each passage had similar growth rates but their longevity decreased slightly with increasing force. These forces had no influence on the proportion of cells attaching to the glass. When the material in the first supernatant was recentrifuged at 2,000 × g for 30 min and added to the cells precipitated in the first centrifugation, the longevity of these cells was increased by several cell divisions. Cells which were not centrifuged but added directly from the cell suspension in trypsin to the new culture grew at a slightly slower rate than the centrifuged cells and became senescent at an earlier time. However, the noncentrifuged cells adsorbed to glass better than those centrifuged.     

Premeiotic aster as a device to anchor the germinal vesicle to the cell surface of the presumptive animal pole in starfish oocytes

The germinal vesicle (GV) of starfish oocytes stays just beneath the oocyte cortex at the presumptive animal pole during the long period of oogenesis. We subjected oocytes to a centrifugal force field to detach the GV from the cortex. The association between the cortex and the GV persisted and withstood a small amount of centrifugal acceleration at 200 g. The GV was eventually separated from the cortex at 700 g. The amount of acceleration sufficient for the GV separation was lowered when the oocytes were pretreated with Nocodazole and was increased by Taxol pretreatment. Observation of microtubular structures with an anti-alpha-tubulin antibody revealed the presence of a complex of spots and radiating arrays as was described by J. J. Otto and T. E. Schroeder (1984, Dev. Biol. 101, 274-281) and called the premeiotic aster. Nocodazole shortened the astral arrays, and Taxol enhanced them. These observations indicate that the premeiotic aster works as a device to hold the GV in an eccentric position just beneath the oocyte cortex.     

Centrifugal elutriation of human lymphoid cells: synchronization and separation of aneuploid cells into diploid and tetraploid populations

Both normal and leukemic human lymphoid cell lines were separated into populations corresponding to different positions in the cell cycle by centrifugal elutriation. Each population was analyzed for cell concentration, cell volume, [3H]thymidine incorporation, percentage S phase by autoradiography, and percent G1, S, and G2/M phases by flow cytometry. The smallest cells, collected at the lowest flow rate, were in G1 phase. Cells collected at increasing flow rates progressively increased in volume and represented distinct positions in the cell cycle transition from G1 phase, through S phase, and into G2/M phase. The purity of the G1 population varied according to cell load. One hundred percent of cells were recovered and cells collected in G1- and S-phase populations proliferated in culture with patterns characteristic of synchronized cells. An aneuploidy leukemia cell line, CEM, was separated into near-diploid and near-tetraploid populations by centrifugal elutriation. This method of cell separation provides large numbers of human lymphoid cells at different positions in the cell cycle for investigating the relationship between the cell cycle and various surface membrane and metabolic properties of cells. Aneuploid leukemia and lymphoma cells can be separated by centrifugal elutriation into populations which contain different numbers of chromosomes for comparisons of their biologic properties.     

Effects of slope, substrate, and temperature on forces associated with locomotion of the ornate box turtle, Terrapene ornata

In spite of several studies of the locomotor performances of reptiles, we know as yet relatively little about the mechanical forces involved. The present investigation examined the effects of substrate, slope and temperature on the pulling forces exerted by ornate box turtles tethered to a force transducer. These forces increased with body mass in a nearly isometric manner. The forces exerted during the initial effort were greatest on a styrofoam substrate, whereas maximum forces generated were greatest on pea gravel. Both forces progressively increased as slope decreased from +30 degrees to -30 degrees. The rate of force generation (N/s) was greatest at intermediate slopes. Contact force tended to increase as normal force increased, and was strongly influenced by slope, increasing from -30 degrees to +30 degrees. Surprisingly, we found no significant effects of temperature on tether forces, contraction times, or rates. This evaluation of pulling forces associated with box turtle locomotion revealed some interesting, and at times unexpected, relationships.     

On the effect of centrifugal force upon antitumor resistance of the organism

The influence of a centrifugal force of 2 g combined with attendant factors, such as noise and electromagnetic field (in all ten exposures, 5 min each, at three- to four-day intervals), on tumor growth in C57Bl/6 mice has been studied. It is shown that the combined treatment leads to enhancement of carcinogenesis. Increasing the centrifugal force to 3 g and the duration of exposure to 15 and 30 min increases the antitumor resistance of the organism and the lifespan. It is assumed that the effect is related to the influence of the centrifugal force on metabolism and to the regularities of adaptation responses of the organism.     

Isolation of intact nuclei of high purity from mouse liver

Current methods of nuclear isolation from liver disrupt the plasmalemmae via homogenization and separation of the nuclei by high centrifugal force (HCF) through gradients of sucrose or other substances for up to 80 min. The use of HCF for such a long time increases the potential for nuclear damage and degradation by endogenous proteases. We compared four combinations of alterations to classical nuclear isolation methods as follows. Mouse liver was gently crushed through a fine mesh with and without in vivo perfusion with collagenase. The cell suspension was centrifuged at 600g to remove gross debris and then at moderate centrifugal force (MCF, 16,000g) or high centrifugal force (HCF, 70,000g) through sucrose gradients for 30 min. The purity of the isolated nuclei was assessed biologically and morphologically, including analyses of representative marker proteins for nuclei and cytoplasm. The results indicate that MCF and no collagenase provided the highest nuclear integrity and purity, whereas MCF with collagenase is a viable option if priority is given to yield. The method is especially suited for small samples and so should facilitate studies with human liver biopsies and livers from mice, the most widely used species for gene targeting.     

Experimental control of the site of embryonic axis formation in Xenopus laevis eggs centrifuged before first cleavage

In Xenopus laevis, the dorsal structures normally develop from regions of the egg opposite the side of sperm entry. Gravity is known to affect this topographic relationship in eggs inclined obliquely from their normal vertical orientation in the period before first cleavage. This effect has been explored in detail, making use of low-speed centrifugation (10-50 g) for short durations (4 min). Eggs were immobilized in gelatin and oriented with their animal-vegetal axes 90 degrees to the force vector, with the sperm entry point (SEP) side of the egg either toward or away from the center of the rotor. It has been found that the egg shows three distinct periods of response to centrifugal force in the interval from fertilization to first cleavage: Prior to 0.4 (40% of the first cleavage interval), the egg is very sensitive to centrifugal force and develops dorsal structures from its centrifugal side, regardless of the position of the SEP in the centrifugal field. Thus, the dorsal structures of the embryo are reversed from normal in eggs centrifuged with the SEP away from the center of the rotor. In the period 0.4 to 0.7, the egg is still very sensitive to centrifugal force and develops dorsal structures from its centripetal side, regardless of the position of the SEP in the centrifugal field. Thus, the dorsal structures of the embryo are reversed from normal in eggs centrifuged with the SEP toward the center of the rotor. In the period 0.7-1.0, the egg becomes increasingly resistant to centrifugal force and forms dorsal structures at the normal position opposite the SEP side. This resistance can be overcome in some egg clutches by 50 g centrifugation followed by prolonged 90 degrees off-axis inclination at 1g. Midway in the second cell cycle, there is a brief period of sensitivity to centrifugal force. These These results are discussed in terms of the types of cytoplasmic rearrangements occurring in the egg at different times of the cell cycle, and in terms of the process of cytoplasmic localization of determinants of dorsal axial development.     

The Effect of Body Pitching on Leg-Spring Behavior in Quadruped Running

<正> In this paper we investigated how the running speed would affect the dynamics of body pitching, and whether body inertiais important for animals. Passive trotting of spring-mass model and passive bounding of spring-beam model were studied atdifferent speeds for different sets of body parameters respectively. Furthermore, different body inertias were used in bounding.We found that running speed exerts effect on leg performance by means of centrifugal force. The centrifugal force can be understoodas an enhancement to the natural frequency of the spring-mass system. The disadvantage of body pitching may beoffset by the great increase in centrifugal force at high speed. The results also reveal that body mass distribution might not be themain reason for the difference in maximal running speeds of different animals.     

Ultracentrifugation of concentrated biopolymer solutions and effect of ascorbate

Highly concentrated solutions of bovine methemoglobin, human transferrin, proteoglycan-protein complex from bovine cartilage, and human hyaluronate were run to equilibrium in the preparative ultracentrifuge. The mass fraction, wo, of water in the compact part of the sediment ("the pellet") was studied as a function of the centrifugal force, ionic strength and pH. For the proteins, wo was close to 0.4 and varied only slightly on variation of the ionic strength and the force. For the proteoglycan-protein complex, wo was close to unity at low force but decreased sharply with increasing force, a finding which agrees well with the specific physical properties of the cartilage matrix. For hyaluronate, wo exceeded 0.8 even at the highest forces, but decreased sharply with increasing ionic strength. There appeared to be a relationship between wo and the carbohydrate mass fraction, wc, of the dry polymer material, wo increasing linearly with wc at 440,000g. A series of biologically or pharmacologically interesting substances was tested for a possible effect on wo of hyaluronate, and it was found that the addition of ascorbate (0.2 g/liter) caused a reduction of 0.040 in wo, independent of the force at which this parameter was measured. Simultaneously, the sedimentation coefficient was doubled. These findings suggest that, on reacting with ascorbate, the hyaluronate molecule changes from a random coil to a more compact molecule.     

Responses of hair cells to statocyst rotation

A new technique is described for stimulating hair cells of the Hermissenda statocyst. The preparation and recording apparatus can be rotated at up to 78 rpm while recording intracellular potentials. Hair cells in front of the centrifugal force vector depolarize in response to rotation. Hair cells in back of the centrifugal force vector hypoerpolarize in response to rotation. Mechanisms by which the hair cell generator potential might arise are examined.     

Tissue length modulates "stimulated actin polymerization," force augmentation, and the rate of swine carotid arterial contraction

"Stimulated actin polymerization" has been proposed to be involved in force augmentation, in which prior submaximal activation of vascular smooth muscle increases the force of a subsequent maximal contraction by ～15%. In this study, we altered stimulated actin polymerization by adjusting tissue length and then measured the effect on force augmentation. At optimal tissue length (1.0 L(o)), force augmentation was observed and was associated with increased prior stimulated actin polymerization, as evidenced by increased prior Y118 paxillin phosphorylation without changes in prior S3 cofilin or cross-bridge phosphorylation. Tissue length, per se, regulated Y118 paxillin, but not S3 cofilin, phosphorylation. At short tissue length (0.6 L(o)), force augmentation was observed and was associated with increased prior stimulated actin polymerization, as evidenced by reduced prior S3 cofilin phosphorylation without changes in Y118 paxillin or cross-bridge phosphorylation. At long tissue length (1.4 L(o)), force augmentation was not observed, and there were no prior changes in Y118 paxillin, S3 cofilin, or cross-bridge phosphorylation. There were no significant differences in the cross-bridge phosphorylation transients before and after the force augmentation protocol at all three lengths tested. Tissues contracted faster at longer tissue lengths; contractile rate correlated with prior Y118 paxillin phosphorylation. Total stress, per se, predicted Y118 paxillin phosphorylation. These data suggest that force augmentation is regulated by stimulated actin polymerization and that stimulated actin polymerization is regulated by total arterial stress. We suggest that K(+) depolarization first leads to cross-bridge phosphorylation and contraction, and the contraction-induced increase in mechanical strain increases Y118 paxillin phosphorylation, leading to stimulated actin polymerization, which further increases force, i.e., force augmentation and, possibly, latch.     

Electroporation of extraneous proteins into CHO cells: Increased efficacy by utilizing centrifugal force and microsecond electrical pulses

A novel electroporation system employing an oscillating electric pulse and centrifugal force was used to introduce extraneous proteins into CHO cells. Following the electrical pulse, the compression and subsequent rebound induced by the centrifugal acceleration and deceleration, respectively, enhanced protein uptake, presumably by a hydrodynamic pumping of extracellular solutions through the permeabilized membrane. Protein uptake was quantitated by measuring the amount of radiolabeled, extraneous, CHO proteins introduced into unlabeled CHO cells. The amount of protein introduced into electroporated CHO cells was enhanced up to four-fold by a combination of electric pulse and centrifugal force compared to that introduced by electric pulse only. The optimum gradient of centrifugal force (GCF, temporal change of centrifugal force) was 590 and -470 g/s during acceleration and deceleration, respectively. The optimum electric field was 5 kV/cm with a 30-microsecond pulse length. At this optimum electroporation condition, approximately 5 pg of proteins (up to 200 kDa molecular weight) were introduced per CHO cell. These same settings also permitted electroporation of other membrane impermeable substances including propidium iodide and ethidium bromide. Introduction of extraneous materials into the cytoplasm during electroporation was confirmed by the ability of anti alpha-tubulin to stain the microtubules and propidium iodide and ethidium bromide to stain the nuclei. Cells electroporated with optimum device settings exhibited no significant decrease in clonogenic survival.     

Experimental demography of rhizome populations of establishing clones of Solidago altissima

1 Solidago altissima forms large compact below-ground rhizome systems. The rhizome systems of 30 genets in a population that had colonized an old-field in 1984 were mapped yearly in situ from 1988 to 1992. Branching angles, lengths and survival of rhizomes, and production of daughter rhizomes, were calculated from digitized maps.
2 We hypothesized that genets of S. altissima would prevent intraclonal crowding by producing longer but fewer rhizomes as they increased in size. In addition, we tested the effects of environmental factors on rhizome dynamics by (i) mowing in late summer, (ii) cutting of rhizome connections, and (iii) removal of close neighbour plants.
3 Most rhizomes were initiated at an angle of 60°−65° relative to the parent rhizome. Subsequent growth tended towards the parent axis and towards more centrifugal growth. Rhizome angles were not influenced by any treatment.
4 In control genets, rhizome density increased 1.3-fold from March 1988 to March 1992. The number of newly produced rhizomes per genet decreased and their length increased from 1988 to 1992. Longer rhizomes had a higher survival probability than shorter rhizomes did. The number of newly produced rhizomes per parent rhizome was positively correlated with mean rhizome length per genet.
5 Mowing strongly decreased rhizome density from 1988 to 1992, mainly due to reduced production of new rhizomes.
6 Rhizome cutting led to a slight decline in the rhizome population and to shorter lengths of rhizomes in their second year compared with controls.
7 The removal of close neighbour plants led to increased rhizome densities. These rhizomes grew longer than controls in unmown plots and shorter in mown plots and had higher probabilities of surviving into their second year.
8 Yearly mowing could successfully prevent the further spread of S. altissima because it acts on rhizome and shoot dynamics as well as on seed output.