Bioeffect of ultrasound on endothelial cells in vitro

The effects of low-intensity ultrasound (US) on biological systems have been investigated extensively; however, the effects of ultrasound stimulation on endothelial cells were rarely studied. In this study, 1 MHz, pulsed 1:4, and four different spatial-average temporal-peak intensities (0.5, 1.0, 1.6, and 2W/cm2) of ultrasound were used to stimulate endothelial cells for 10 min per day. The results showed that ultrasound (intensity 1.6-2.0W/cm2) treatment after 6 days enhanced the nitric oxide (NO) and Ca2+ release from the endothelial cells but did not promote cell growth. In addition, ultrasound stimulation changed the cellular morphology and orientation, and increased extracellular matrix secretion from endothelial cells.     

Enhanced co-production of pectinase,cellulase and xylanase enzymes from Bacillus subtilis ABDR01 upon ultrasonic irradiation

The effect of low-intensity ultrasound irradiation was studied to improve the co-production for pectinase, cellulase, and xylanase enzymes using Bacillus subtilis ABDR01. Different parameters such as ultrasonic irradiation at the different growth phases of the bacterial strain, ultrasound power, irradiation duration, and irradiation duty cycle were assessed. Sonication with 90 W ultrasound power, 25 kHz frequency with 70 % duty cycle for 5 min at 6 h of bacterial growth phase gave the maximum productions of 87.82 U/ mL pectinase 22.17 U/ mL cellulase and 137.95 U/ mL xylanase respectively. The enzyme activity of pectinase, cellulase, and xylanase was enhanced by about 38.15 %, 53.77 %, and 24.59 %, respectively, compared to non-sonicated control cultivation. This optimized low-frequency ultrasound irradiation to bacterial cells enhanced the nutrient uptake rate and increased the cell wall permeability, which results in higher enzyme productivity. Our results signify the effectiveness of low-frequency ultrasound irradiation for improved enzyme yields and hyperactivation during microbial fermentation.     

Laser effects on cellular adhesion and influence on the interrelation between HeLa S3 and human diploid cells

The interactions between HeLa S3 tumoral cells and human fibroblasts after nitrogen-laser irradiation (337.1 nm) have been studied by using an in vitro cell invasion model. For the quantitative and morphological evaluation of nitrogen-laser radiation action upon tumoral adhesion to the fibroblast monostrate, we used: a) 3H-thymidine labelling of HeLa S3 tumoral cells; b) morphological modifications studies by phase contrast and scanning electron microscopy. The results emphasized the following aspects: 1. In non-irradiated cell cultures we noticed three interaction stages: adhesion, tumoral spreading and displacement with fibroblasts destruction; on the other side, we found a reduced adhesion to non-irradiated human fibroblasts of laser irradiated tumoral cells. 2. Significant percent increasing of non-irradiated tumoral cells adhesion to fibroblast monostrate, irradiated with various laser fluences (e.g. 0.2 kJ/m2--48.1%; 0.8 kJ/m2--63.8% and for 1.6 kJ/m2--79.5%). This phenomenon evidenced the close interrelation between irradiation fluences and tumoral adhesion rates. 3. The importance of numerical ratio between tumoral cells and fibroblasts in tumoral adhesion and invasion processes (e.g. ratio 1:10 tumoral adhesion reached 8.1%; in 1:5--25.9%; in 1:1--59.4% and for 2:1--83.9%). 4. Marked cytotoxic effects for both cell types after exposure to high and very high laser fluences (1.6--6.4 kJ/m2). Our results emphasize near UV-laser irradiation effects upon some of tumoral adhesion and invasion mechanisms and demonstrate the interrelations between cell populations manifesting a different vital potential.     

甲苯胺蓝介导的超声疗法对牙菌斑中细菌灭活效果的研究

目的：验证甲苯胺蓝介导超声对龈上牙菌斑中细菌的抑制作用。方法：从门诊20例牙周炎病人下前牙区取龈上菌斑一份,每个患者的菌斑于实验室培养后,在同一甲苯胺蓝浓度下与不同超声强度联合作用,利用涂板计数法分析其对菌斑中细菌的抑制作用。实验分组：空白组、单独甲苯胺蓝组、单独超声组、甲苯胺蓝＋超声组。结果：单独超声作用时没有灭菌效果,细菌数目反而有所增长（P〈0.05）,超声联合甲苯胺蓝作用时取得明显的灭菌效果,超声强度2W/CM2灭菌率可达到79%。结论：低强度超声能够促进细菌生长,甲苯胺蓝介导一定强度的超声疗法对龈上牙菌斑中的细菌有良好的抑制作用。     

Ultrasound enhanced bioprocesses: cholesterol oxidation by Rhodococcus erythropolis

Cholesterol oxidation to cholestenone by resting cells of Rhodococcus erythropolis ATCC25544 was investigated under a computer-controlled ultrasonic irradiation at a frequency of 20 kHz. The optimization of the ultrasound intensity and its mode of application to a stirred bioreactor was first established at a level which preserved the structural integrity of the cells and enabled their metabolic activity. A significant enhancement in the kinetic rates of the biotransformation was observed in microbial slurries of 1.0 and 2.5 g/L cholesterol when sonicated for 5 s every 10 min with a power output of 2.2 W/cm(2). In contrast, ultrasound had no effect on the enzymatic oxidation of cholesterol (2.5 g/L) by cholesterol oxidase. A high loading of cholesterol (5.0 g/L) in sonicated microbial systems had, however, an adverse effect. The ultrasound enhancement is discussed in terms of an increased dissolution rate of the sustrate crystals and more importantly, in terms of the uniquely ultrasound-induced enhancement of mass transfer inside and outside a cell.     

Effects of 2.45-GHz microwaves on primate corneal endothelium

Both eyes of anesthetized cynomolgus monkeys (Macaca fascicularis) were irradiated with 2.45-GHz microwaves, either pulsed or continuous wave. In vivo corneal endothelial abnormalities were observed by specular microscopy and confirmed through histologic techniques after a 16- to 48-hour postexposure period. Pulsed microwaves with an average power density of 10 mW/cm2 (equivalent to a specific absorption rate (SAR) = 2.6 W/kg) produced these effects, while levels of 20-30 mW/cm2 (equivalent to a SAR = 5.3 to 7.8 W/kg) with continuous wave irradiation were required to produce similar changes.     

Irradiation of the template with high-intensity (pulse-laser) ultraviolet light results in DNA-polymerase termination events at deoxyguanosine residues

During primer elongation by Escherichia coli DNA-polymerase I large fragments on the template were irradiated with UV laser pulses at an intensity greater than or equal to 10(10) W/m2. In addition to the termination events at photoproducts typical of low-intensity UV irradiation, termination is observed before deoxyguanosine residues. The effect of the UV light intensity on the ratio of termination efficiencies before dPy and dG suggests that the termination of polymerization before deoxyguanosine residues results from the formation of photoproducts yielded by two-quantum reactions. The results obtained herein, together with data published previously, imply that photomodification of dG residues is the major two-quantum reaction under the action of high-intensity UV radiation on DNA.     

Behavior of confluent endothelial cells after irradiation. Modulation of wound repair by heparin and acidic fibroblast growth factor

Image analysis was used to study the repair process of a circular mechanical lesion of confluent human endothelial cells in culture after irradiation (10 Gy) prior to wounding. Coverage of denuded areas 48 and 96 h after injury of endothelial cells was identical in control and irradiated cultures, although the labeling index was lowered by 80 to 95% in irradiated cultures. The cell density of non damaged irradiated areas was decreased by 50%. When cultures were submitted to increasing doses of radiation (5.0-30 Gy), the labeling index of the cells diminished rapidly between 0 and 5.0 Gy and reached a plateau at 10 Gy. The decrease in cell density (50% of control at 96 h) was identical at each dose of radiation. Thus cell migration alone could be sufficient for the repair of the lesion, while cell proliferation would mainly maintain the original cell density. The addition of heparin to the culture medium slowed down cell migration and proliferation, but the speed of repair was identical in irradiated and non-irradiated cultures. Acidic fibroblast growth factor plus heparin accelerated equally the repair process whether the cultures were irradiated or not. In irradiated cultures the presence of acidic fibroblast growth factor and heparin maintained cell density in confluent areas at a level similar to that in non-irradiated damaged control cultures without addition of mitogens. Thus heparin and acidic fibroblast growth factor play a role in cell proliferation, in the maintenance of the cell monolayer integrity and in restoring a continuous layer by rapid cell migration and elongation after irradiation.     

Behavior of confluent endothelial cells after irradiation. Modulation of wound repair by heparin and acidic fibroblast growth factor

Image analysis was used to study the repair process of a circular mechanical lesion of confluent human endothelial cells in culture after irradiation (10 Gy) prior to wounding. Coverage of denuded areas 48 and 96 h after injury of endothelial cells was identical in control and irradiated cultures, although the labeling index was lowered by 80 to 95% in irradiated cultures. The cell density of non damaged irradiated areas was decreased by 50%. When cultures were submitted to increasing doses of radiation (5.0–30 Gy), the labeling index of the cells diminished rapidly between 0 and 5.0 Gy and reached a plateau at 10 Gy. The decrease in cell density (50% of control at 96 h) was identical at each dose of radiation. Thus cell migration alone could be sufficient for the repair of the lesion, while cell proliferation would mainly maintain the original cell density. The addition of heparin to the culture medium slowed down cell migration and proliferation, but the speed of repair was identical in irradiated and non-irradiated cultures. Acidic fibroblast growth factor plus heparin accelerated equally the repair process whether the cultures were irradiated or not. In irradiated cultures the presence of acidic fibroblast growth factor and heparin maintained cell density in confluent areas at a level similar to that in non-irradiated damaged control cultures without addition of mitogens. Thus heparin and acidic fibroblast growth factor play a role in cell proliferation, in the maintenance of the cell monolayer integrity and in restoring a continuous layer by rapid cell migration and elongation after irradiation.     

Influence of low-intensity ultrasonic irradiation on prenatal development of two inbred mouse strains.

Effects of low-intensity ultrasonic irradiation on prenatal development of DHS and A/HeMk mice were studied. On day 8 of gestation (VP day = 0) pregnant females were exposed to ultrasonic waves with a frequency of 2.25 MHz and power of 40 mW/cm2 for 5 h. A low frequency of severe cranial and facial anomalies occurred that was attributable to the irradiation in both strains. The difference in frequency of malformed fetuses was marked between irradiated and untreated control A/HeMk mice, but not DHS mice. Fetal growth inhibition and death were also produced in both strains, although the possible effect of binding the pregnant mice for irradiation cannot be discounted.     

A model system and technique to study the effects of ultrasound irradiation on embryonic development

To study the effects of ultrasound on development it is important to have a system which provides reliable results. We have designed a system which allows for reproducible irradiations of chick embryos in ovo. The irradiation system includes a heated sonation tank with ultrasound absorbers and a PC/AT computer-based data acquisition system for on-line monitoring of irradiations. The ultrasound detection microprobe and irradiation transducers were calibrated against an NBS traceable balance meter. An acoustic spacer was utilized to provide a more uniform profile of the irradiation beam. At the position of the embryo the ultrasound field geometry was determined. To maintain the chick embryo in its natural physiological state while minimizing ultrasonic reflections and standing-wave generation, two diametrically opposed windows were made in the eggshell along the ultrasound pathway and covered with polyethylene membranes. Using this irradiation system at intensity levels as high as 1.1 W/cm2 (spatial average, temporal average) for 10 min, the temperature rise is minimal.     

Induction of adhesion-dependent signals using low-intensity ultrasound

In multicellular organisms, cell behavior is dictated by interactions with the extracellular matrix. Consequences of matrix-engagement range from regulation of cell migration and proliferation, to secretion and even differentiation. The signals underlying each of these complex processes arise from the molecular interactions of extracellular matrix receptors on the surface of the cell. Integrins are the prototypic receptors and provide a mechanical link between extracellular matrix and the cytoskeleton, as well as initiating some of the adhesion-dependent signaling cascades. However, it is becoming increasingly apparent that additional transmembrane receptors function alongside the integrins to regulate both the integrin itself and signals downstream. The most elegant of these examples is the transmembrane proteoglycan, syndecan-4, which cooperates with α(5)β(1)-integrin during adhesion to fibronectin. In vivo models demonstrate the importance of syndecan-4 signaling, as syndecan-4-knockout mice exhibit healing retardation due to inefficient fibroblast migration. In wild-type animals, migration of fibroblasts toward a wound is triggered by the appearance of fibronectin that leaks from damaged capillaries and is deposited by macrophages in injured tissue. Therefore there is great interest in discovering strategies that enhance fibronectin-dependent signaling and could accelerate repair processes. The integrin-mediated and syndecan-4-mediated components of fibronectin-dependent signaling can be separated by stimulating cells with recombinant fibronectin fragments. Although integrin engagement is essential for cell adhesion, certain fibronectin-dependent signals are regulated by syndecan-4. Syndecan-4 activates the Rac1 protrusive signal, causes integrin redistribution, triggers recruitment of cytoskeletal molecules, such as vinculin, to focal adhesions, and thereby induces directional migration. We have looked for alternative strategies for activating such signals and found that low-intensity pulsed ultrasound (LIPUS) can mimic the effects of syndecan-4 engagement. In this protocol we describe the method by which 30 mW/cm(2), 1.5 MHz ultrasound, pulsed at 1 kHz (Fig. 1) can be applied to fibroblasts in culture (Fig. 2) to induce Rac1 activation and focal adhesion formation. Ultrasound stimulation is applied for a maximum of 20 minutes, as this combination of parameters has been found to be most efficacious for acceleration of clinical fracture repair. The method uses recombinant fibronectin fragments to engage α(5)β(1)-integrin, without engagement of syndecan-4, and requires inhibition of protein synthesis by cycloheximide to block deposition of additional matrix by the fibroblasts. The positive effect of ultrasound on repair mechanisms is well documented, and by understanding the molecular effect of ultrasound in culture we should be able to refine the therapeutic technique to improve clinical outcomes.     

1.5 MHz ultrasound irradiation of human lymphocytes.

Human lymphocyte cultures are exposed to 1.5 MHz continuous wave ultrasound, and it is demonstrated that cell death, as monitored by pyknosis, follows immediately on sonication at intensities within the usual therapeutic range (less than 1.7 W/cm2,spatial average). The number of cells affected is determined by the ultrasound intensity only, but the rate at which they proceed through their pyknosis cycle is modified by both the intensity and the duration of exposure. There is a clear indication of an intensity threshold for the effect approximately 1.1 W/cm2. Pulsed 1.5 MHz ultrasound (70 mus, 1 :1 pulses, 1.7 W/cm2 space-time average) results in a 15-20 hour delay in the measurable response to sonication. It is shown that the intracellular presence of a lysosomal-enzyme inhibitor strongly modifies the course of the ultrasound action. Evidence is presented to suggest that the basic interaction mechanism is via a cavitation process, but there are some difficulties with this interpretation, which are also discussed.     

Effects of in vivo ultrasound hyperthermia on natural killer cell cytotoxicity in the hamster

The effects of in vivo ultrasound irradiation of the spleen on immunological functions were assessed with an in vitro natural killer (NK) cell cytotoxic assay. Anesthetized hamsters were exposed to 1 MHz ultrasound at intensity levels currently being used clinically for therapeutic diathermy and hyperthermia (1-5 W/cm2, for 500 sec with constant beam scanning). Hyperthermic levels in the spleen ranged from 38-43 degrees C. Significant depression of natural killer (NK) cell activity was seen 4 h after spleen irradiation as compared to sham irradiated and normal animals. A return towards normal levels was observed in experimental groups at 24 h after exposure. Sham and normal animals were not significantly different in NK activity, indicating no significant stress-related immunosuppressive effects due to handling. Differential leukocyte counts taken for each exposure condition showed significant lymphopenia at 4, 8, and 16 h after exposure, near normal levels at 24 h, and complete recovery by 48 h. The number of circulating mononuclear cells at 4 h showed a dose-related suppression as the exposure intensities were increased.     

Repair of radiation induced DNA damages in unicellular green algae

Two cell repair systems--photoreactivation and repair of single-strand DNA breaks have been studied using unicellular green algae as a test-system. Effects of the genotype and the intensity of pico/second UV-laser irradiation on the degree of the photoreactivation have been investigated. It has been shown that the lower intensity (I = 8.10(6) W/cm2) effects less the inactivation of living cells comparing with I = 30.10(6) W/cm2, regardless of the genotype. The clearly expressed higher potentials of strains LARG-1 and 260 to produce and repair alterations of the cyclobutane-pyrimidine dimers type have been established. An analysis of DNA degradation during gamma rays irradiation and after incubation has been carried out for investigation the relationship between strains radioresistance and repair of single-strand break. It has been shown that high efficiency of the repair system is characteristic of the resistant strain obtained from chronically irradiated population.     

Influence of variuos ultrasound regimens on oxide-modified actomyosin superprecipitation reaction from skeletal muscle of rabbit

A comparative study of rabbit skeletal muscles oxide-modified actomyosin superprecipitation reaction in dependence on continuous and impulsive (2 ms) ultrasound regimens was studied. From the analyses of kinetic curves the effect of the value of superprecipitation (A(m) - A(0)), time t1/2, required for achievement of half of its value was determined, and the normalized maximal rate of this reaction V was also calculated. It is shown that the use of continuous ultrasound to oxide-modified actomyosin was associated with a significant decrease of superprecipitation relative to controls. However, pulsed ultrasound caused a significant increase in superprecipitation value except for the values (A(m) - A(0)) in the application of the intensity of 0.2 W/cm2. The oxide-modified actomyosin superprecipitation value under the effect of continuous and impulsive ultrasound at intensity 1 W/cm2 in relative to control and all other applied intensities decrease to the most extent. It is caused perhaps by thermal influence of ultrasound. In general, the data obtained give reason to assume that the effects of continuous and pulsed ultrasound on the reaction of oxide-modified proteins complex superpretsipitatsii identical.     

Karyometric observations of WISH cell cultures irradiated with 3 GHz microwaves.

WISH cell cultures 24 hours after passage were irradiated with 3 GHz microwaves (10 cm) at far field conditions in free space (anechoic chamber) for 30 minutes, at field power density 5 or 20 mW/cm2. Within 1,24 and 48 hours of the exposure to microwave fields the volumes of nuclei and nucleoli were measured with the use of a micrometer, and logvolumes and nucleo-nucleolar ratios were calculated. Under the applied irradiation conditions the culture medium temperature did not exceed 37 degrees C. In cultures irradiated at field power density 20 mW/cm2 increased number of cells with small nuclei and enlarged nucleoli was noted within 1 hour of the exposure. Within 24 and 48 hours after irradiation the nucleolar volume showed a slight decrease, whereas the nuclear volume increased. In cultures irradiated at field power density 5 mW/cm2 increased numbers of cells with enlarged nuclei and nucleoli were found. Analysis of the distribution curves of nuclear and nucleolar volumes suggests that non-thermal power densities of microwaves stimulate the metabolism of cell cultures. However, at higher power densities (20 mW/cm2) the stimulation phase is preceded by a period of reduced viability of cell cultures.     

Observations on the effect of X-ray alone and in combination with ultrasound on human chromosomes

Summary Human peripheral blood was treated with ultrasound either before or after irradiation, and chromosome aberrations in lymphocytes of peripheral blood cultures compared to those resulting from an equivalent dose of irradiation given alone.When peripheral blood is sonicated at a high intensity (3 W/cm²) for 10 min after irradiation, there is an increase in aberration frequency as compared to control samples receiving the equivalent radiation dose alone. However, should the blood be sonicated at the same frequency and for the same time period before radiation there is no significant increase in total chromosome aberrations over the irradiated controls. On the contrary a significant decreases occurs in certain classes of aberration.When sonification with a lower intensity (20 mW/cm²) was used in combination with irradiation the reverse effect was noted. Ultrasound administered for 10 min after radiation caused no significant increase in aberrations. On the contrary increasing the period of sonification to one hour resulted in a lowering of all types of aberration, significant in the case of dicentrics and total chromosome aberrations, when compared to irradiation alone. Reversing the order of treatment again resulted in the opposite effect to that achieved with comparable experiments at high intensities of sonification. Ultrasound before radiation did not produce lower breakage rates. Instead, when the period of sonification was increased to one hour, the number of aberrant cells, fragments, and total aberrations rose significantly over controls.It is suggested that sonification produces chemical changes affecting cellular repair systems, which when combined with ionising radiation, results in an increased or decreased repair effect depending on the dose, duration, and order of treatment.Dedicated to Prof. Dr. Felix Mainx on the occasion of his 80th birthday     

He—Ne激光照射离体鼠巨噬细胞对线粒体跨膜电势的影响

目的：研究Ｈｅ－Ｎｅ激光照射鼠巨噬细胞对线粒体跨膜电势的影响,及其与激光剂量的关系。方法：用亲脂性阳离子荧光染料Ｒｈｏｄａｍｉｎｅ１２３对鼠巨噬细胞线粒体作荧光标记,以不同的激光剂量照射,采用图像分析系统（ＩＡＳ）和荧光显微镜观察线粒体跨膜电势荧光强度的变化。结果：低功率Ｈｅ－Ｎｅ激光照射５,１０,１５ｍｉｎ,激光剂量分别为０．６４９,１．３８８和２．０８２Ｊ／ｃｍ＾２,巨噬细胞线粒体跨膜电势荧光     

Low-intensity pulsed ultrasound stimulates a bone-forming response in UMR-106 cells

Low-intensity (<100 mW/cm(2)) pulsed ultrasound (US) is an established therapy for fracture repair. In both animal and human trials, such US has been shown to facilitate fresh fracture repair and initiate healing in fractures with repair defects. However, the mechanism by which US achieves these outcomes is not clear. One possible mechanism is the direct stimulation of bone formation. To investigate this hypothesis, the current study investigated the mRNA response of isolated bone-forming cells (UMR-106 cells) to a single 20-min dose of low-intensity pulsed US. Using a novel US-cell coupling method, US was found to stimulate expression of the immediate-early response genes c-fos and COX-2 and elevate mRNA levels for the bone matrix proteins ALP and OC. These findings suggest that low-intensity pulsed US has a direct effect on bone formation. This may contribute to the beneficial effect of low-intensity pulsed US on fracture repair.