前苏联专利SU1168104A3 Device for determining volume of buffer layer of anticoagulated blood clot

专利PDF首页>>前苏联专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
A technique for generally determining the volume of a layer of a constituent material in a centrifugally separated mixture of material. A centrifuge tube is used to hold the material mixture and an appropriately shaped body is disposed in the tube in the zone occupied by the constituent material whose volume is to be measured. The body reduces the available volume within the tube which may be occupied by the constituent material, and thus expands the axial extent of the constituent material to make visual measurement of the constituent material more accurate.
公开号:SU1168104A3
申请号:SU772466662
申请日:1977-03-31
公开日:1985-07-15
发明作者:С.Вордлоу Стефен；А.Левайн Роберт；В.Масси Джеймс
申请人:Стефен С.Вордлоу, Роберт А.Левайн и Джеймс В.Масси III (US)；
IPC主号:

专利说明:

one
This invention relates to medical laboratory equipment and relates to devices for quickly visually measuring the approximate volume of a layer of a component of a material in a centrifuged mixture of materials.
Various methods have been proposed for measuring the volume of a layer that is a component of a mixture of materials (and this mixture was centrifuged to separate the layers forming the material according to density or specific weight). Such methods have found particular use for measuring components of various biological fluids, such as blood. The most difficult to quickly and easily measure blood component is a buffer layer consisting of various types of cell proteins and platelets. In the centrifuged anticoagulated complex of the whole blood sample, the buffer layer is placed between the red cell layer and the plasma layer, however, due to the insignificant size of the buffer layer, there is still no fast method for its measurement.
One method for determining the white cell count is to use an accurately measured volume of whole blood, which is diluted and placed in an optical counting chamber of a given volume. A sample of the diluted blood is examined with a microscope and the white blood cells, or leukocytes, are visually counted. This method is time consuming, relatively expensive equipment, and it has errors due to inaccurate measurement and inaccurate sample dilution.
A device for determining the volume of the buffer layer of a blood clot of anticoagulated blood is known, which contains a transparent cylindrical container for a centrifuged blood sample. The vessel is a centrifuged container with a middle axial zone with a narrowed inner diameter, which forms a narrow vertical column of white blood cells due to the reduced volume. In such a case, to lift a blood sample so that the leukocytes can occupy the narrow median axial chon of the vessel, material is required.
density, such as mercury. Leukocytes that have been properly positioned are aspirated out of the vessel and undergo further investigation.
However, the known device does not allow to quickly and accurately determine the volume of the buffer layer, while the visual assessment is difficult.
0 The purpose of the invention is to accelerate the determination and increase the objectivity of the visual determination.
The goal is achieved by the fact that the device for determining
5 of the volume of the buffer layer of the blood clot of the actikoagulyatirovanny blood, containing a transparent cylindrical container for the centrifuged blood sample, is equipped with a float made of a specific material. weighing 1.02-1.09 g / cm, having an elongated shape, the capacity being a capillary tube, and the float is installed inside the latter with the formation of a gap with the inner surface of the tube. Figure 1 shows the device in disassembled form; Fig. 2 is an axial section of a cap tube; on
0 FIG. 3 is an axial section of the device (FIG. 1) when used for visual calculations} in FIGS. 4-6, some perspective images are some. float options; figure 7 is an axial section of a modified float shown in figure 3; -fig.8 - axial section of the modified float shown in, 6, figures 9 and 10 - various embodiments of the float, which can be used as a volume-occupying mass.
Figure 1 shows one of the forms of implementation of the device, which
It can be used to visually determine the approximate number of white cells and platelets in a whole blood sample. The device has a capillary tube 1 of conventional construction with an opening 2, which can be open at both ends of the tube 1. Inside the tube 1 is placed a float 3. In Fig. 1, the float 3 has the form of a straight cylindrical or plug-shaped insert,
made of material having a specific weight of 1.02-1.09 g / cm, whereby the float floats on the ground
3
centrifuged red cells. Due to its shape, the float 3 is held in the opening 2 of the tube 1, since the axes of both in the main VI coincide. The diameter of the float 3 is small enough relative to the diameter of the opening 2 of the tube 1 so that it can slide in the opening of the tube and shift during the centrifugation of the blood sample into the layer of red cells and float in it after centrifugation.
The difference in the respective diameters of the float 3 and the opening 2 of the tube 1 forms a gap of limited volume and this volume is occupied by a centrifuged layer of white cells and platelets. By limiting the size of the volume that is free for the buffer layer, it is possible to increase the height or thickness of the buffer layer compared to this parameter in an unlimited diameter channel of the capillary tube. In this way, an increase in the volume of the buffer layer in the blood samples studied is provided; this will allow determining the level of white cells and platelets: high, low or medium. The result of such a general definition will show the need to carry out other more accurate analyzes. The degree of increase in the height of the buffer layer can be changed by changing the difference in the diameters of the float 3 and the opening 2 of the tube 1. Thus, the expansion factor can be achieved from four to twenty. For example, the expansion factor 9 can be achieved. The apparent elongation of the buffer layer is due to the fact that the volume occupied by the float 3 in tube 2 is placed against the layer of red cells, and this reduces the free volume for the buffer layer by 0.75 times or more,
Fig. 2 shows a capillary tube 1 containing a blood sample with layers of its components separated by centrifugation. The lower end of the tube aperture is closed with a plug 4 made of clay, wax, etc., before centrifugation. The height of the red cell layer is usually indicated by R, the height of the white cell and platelet layer, t, e, of the buffer layer. B, and the height of the plasma layer is R. Osev. The extent of the white cell and platelet layer B is very small and not 681044
it is possible to detect abnormally high or low or medium white cell and platelet counts,
The sample is subjected to centrifugation in tube 1, into the hole of which a volume-filling float 3 is inserted. As can be seen from FIG. 3, the hole
IQ 2 tubes and side surface
the float 3 forms directly above the red cell layer R an annular gap V, which in the centrifuging process fills with buffer
by layer. The annular gap V is considerably narrower than the corresponding free space in the tube opening. The axial strike of the buffer layer occupying the gap significantly increases from this, t, e, the distance
between the upper and lower meniscus of the buffer layer is much larger than that shown in FIG. 2. In order to visually determine the number of white cells and platelets, the minimum increase in the length of the layer should be at least 4 times. If desired, an apparatus for determining high, low or medium white blood cell and platelet counts can be used.
The scale is 5. On the scale 5 there are marks, indicating high, low and medium levels of the buffer layer. Measurement of the distance by the upper and lower meniscus of the buffer meniscus
This layer allows to determine the content of white cells and platelets. With the help of the device shown in FIG. 3, it is possible, using mechanical optical or electrical means.
to estimate the relative axial elongation of the buffer layer.
The device is applied as follows.
The float 3 is inserted into the opening 2 of the tube 1, after which the ends of the tube can be bent inward so that the float cannot fall out of the tube, or the float 3 can be glued to
the wall of the opening 2 tubes 1 blood-soluble composition, such as gum arabic. Tube 1 is then used in the usual manner to take a blood sample from a patient by pressing with a finger or t, p. Selected
the sample is centrifuged, as a result, the separation and elongation of the buffer layer occurs (see FIG. 3). An axial oblong shape of the float 3 can be obtained by melt extrusion of a synthetic resin, followed by cutting the extruded material into segments of the desired length. Floats can also be prepared by pouring molten resin under pressure. The specific gravity or transverse bulk density of the material is 1.021, 09 g / cm, preferably about IjOA g / cm, whereby the float 3 floats on the red cell layer and is immersed in the buffer layer. Acronitrile-butadienenitrile can be used as acceptable material styrene and stol copolymer MMA. To form the insert, you can also use a material from several layers of different suitable weights, so long as the specific volume weight of the multilayer material has a specified value. In Figures 1 and 3, the float 3 has a straight cylindrical shape, and in Figures 4-6 and to, floats of a different configuration are shown. Figure 4 shows a float having one or more axial channels formed on its lateral surfaces. The channels form passages in which a buffer layer is placed during the centrifuging process. Figure 5 shows a float with a cylindrical side wall. In the latter, an axial channel is formed, in which the buffer layer is located. The channel has a narrowed mouth at the bottom. The channel volume expands logarithically from the mouth to the upper end. The use of a logarithmic or non-linear scale expansion channel provides more accurate determined the number of white cells and platelets in the case of large dispersion of the result
tat, taking place at abnormally low or abnormally high number of counted units. Fig, 7 shows the logarithmic slope of the channel wall.
Fig. 6 shows a float, the lower end of which is located near or inside the layer of red cells. The float may have a cylindrical shape in a short section. The side wall of the float then has a logarithmic or other non-linear inclination that extends upwards into the axis.
To further increase the length of the buffer layer, microspheres can be applied to the outer surface of the float or any channels formed in it. Microspheres can be glued to each other and to the float with the help of soluble glue, for example with the help of blood soluble in blood,
The use of an axially elongated float allows a multiple increase in the length of the axially elongated layer, in particular, about 4 towards the upper end of the float. Fig, 8 shows the logarithmic slope of the side wall to the axis. This configuration improves the counting accuracy over a wide range of cell contents due to a logarithmic or non-linear increase in the size of the free space between the side wall of the insert and the wall of the tube opening, in which the buffer layer is located. 10 shows a float in the form of a stepped cylinder. The lower zone itself has the largest diameter, which ensures a large multiple extension of the buffer layer, for example, by a factor of 20. The upper zone has a smaller diameter and provides a smaller coefficient of elongation of the buffer layer, for example, threefold. The insert provides multiple linear elongation of the buffer layer, and can be used to quickly detect an unusually large number of white cells and Platelets. A high content of the latter is detected by the exit of the buffer layer beyond the stage. A zone of smaller diameter gives an idea of how much the number of white cells and platelets is above normal. Figure 9 shows the float tsilin-. It has an elongated handle that aids in the insertion of a float into a capillary tube and protrudes beyond the end of the latter. The handle can be taken by hand after the blood sample has been inserted into the capillary tube, and by pumping up and down to ensure that the paint is mixed with the blood. The handle can be attached to the float of the weakened zone, whereby it can be torn off from the insert after mixing, but before centrifugation. 4-20 times. When determining the number of white cells and platelets in a blood sample, preference is given to increasing the axial length of the layer of white cells by about 5-15 times. .. Multiple lengthening of the buffer layer in the specified preferred range leads to stratification according to the specific gravity of the individual components of the buffer layer, to polymorphic cells and mononuclear cells, including lymphocytes, monocytes and platelets. The components of the buffer layer are stratified in the order of specific gravity, first polycells, then mono lymphocytes (in one layer), and then platelets. By making the float from a material of the indicated specific gravity with an appropriate degree of axial elongation, the float easily sits on the upper part of the red cell layer of the centrifuged blood sample. It is in this part of the red cells that reticulocytes or immature border cells are located during centrifugation. The float, therefore, causes the axial lengthening of the reticulocytic sublayer of the red cell layer. It turned out that adding fluorescent paint to the blood sample allows an approximate reticulocyte count. This result may help the physician in determining the degree of new red cells in the patient's blood. Before observing the internal stratification of the buffer layer and the layer of reticulocytes, a fluorescent dye, such as Acridine orange 04, can be introduced into the sample before centrifugation. Ink is absorbed to varying degrees by various components of the buffer layer and reticulocytes. In the light, different layers have different degrees of fluorescence. By illuminating a tube with light with an appropriate wavelength, it is possible to determine the thickness of each sublayer of the buffer layer and the thickness of the reticulocyte layer. If desired, delamination can be observed by optical magnification. The paint can be applied to the wall of the tube orifice, it can be covered with a float, or it can be inserted into the float in the form of self-holding, but soluble mass. When using non-anticoagulated blood, blood can also be injected in the same way. The device according to the invention provides a ninefold axial increase in the distance between the upper and lower meniscuses of the buffer layer of centrifuged whole blood, has a capillary tube, and is centrifuged to a tube with an internal diameter. rum is 0.05575 inches (1.42 mm). The float is a straight cylinder made of Rexolite, a cross-linked styrene with a specific weight of 1.04 g / cm, diameters of 0.053 (1.35 mm), height of about t / 2 (12 , 7 mm). The invention will provide a quick and cheap estimate of the number of white cells and platelets in a centrifuged whole blood sample. Using proper multiple elongation of the buffer layer, a device can be used to make a differentiated assessment of white cells and platelets. PJt FIG 3
fig L
FIG. five
Figs with
Fi8.7
Fi.Z
Fie.8
FIG. W

权利要求:
Claims (1)
[1]
DEVICE FOR DETERMINING THE VOLUME OF THE BLOOD BUFFER LAYER
A CLOT OF ANTI-AAGULATED BLOOD, containing a transparent cylindrical container for centrifuging a blood sample, characterized in that, in order to accelerate the determination and increase the objectivity of the visual determination, it is equipped with a float made of a material with a specific gravity of 1.021.09 g / cm ³ having an elongated shape while the capacity is a capillary tube, and the float is installed inside the latter with the formation of a gap with the inner surface of the tube.
FIG. 1
SP with _t 1168104
eleven

类似技术:

公开号 | 公开日 | 专利标题

SU1168104A3|1985-07-15|Device for determining volume of buffer layer of anticoagulated blood clot

US4137755A|1979-02-06|Material layer volume determination

US4066414A|1978-01-03|One piece tube and microscope slide manipulative laboratory device

RU2100807C1|1997-12-27|Method to determine distribution of probabilities of erythrocytic subsets in erythrocytic populations in whole blood sample and device for its implementations

EP0200303A1|1986-11-05|Measurement of a small most dense constituent layer in a stratified mixture

US4774965A|1988-10-04|Material layer volume determination with correction band

US4788154A|1988-11-29|Method and apparatus for obtaining and delivering a predetermined quantity of plasma from a blood sample for analysis purposes

US6153148A|2000-11-28|Centrifugal hematology disposable

EP0494079B1|1997-03-26|Quantification of fibrinogen in whole blood samples

US3914985A|1975-10-28|Centrifuging device and method

US5844128A|1998-12-01|Method and apparatus for rapid determination of blood sedimentation rate

US20040019300A1|2004-01-29|Microfluidic blood sample separations

CA1319269C|1993-06-22|Method for measuring hemoglobin

US4409820A|1983-10-18|Apparatus and method for use in quantitative analysis of a fluid suspension

US8093015B2|2012-01-10|Method for determining the viability of cells in cell cultures

US3963119A|1976-06-15|Serum separating apparatus

US4563332A|1986-01-07|Liquid sampling apparatus with retention means

US5830639A|1998-11-03|Method for analyzing blood samples

US4823624A|1989-04-25|Material layer volume determination with correction band

US4875364A|1989-10-24|Method for measuring hemoglobin

US4043928A|1977-08-23|Serum separating composition of matter

Bull et al.2001|Is the packed cell volume | reliable?

EP0111551B1|1987-05-06|Process and apparatus for measuring blood viscosity directly and rapidly

JPH08292190A|1996-11-05|Blood examination container

WO2018164686A1|2018-09-13|Device and method of fluid assay

同族专利:

公开号 | 公开日

DE2714763C3|1981-04-09|

ATA234477A|1980-10-15|

AU501618B2|1979-06-28|

AU2388077A|1978-12-07|

US4091659A|1978-05-30|

US4027660A|1977-06-07|

CH624215A5|1981-07-15|

BR7702079A|1978-01-24|

US4077396A|1978-03-07|

MX145210A|1982-01-14|

ZA771226B|1978-08-30|

NZ183621A|1979-12-11|

ES460989A1|1978-05-01|

FR2346692A1|1977-10-28|

ES460990A1|1978-05-01|

US4082085A|1978-04-04|

SE426268B|1982-12-20|

CH625624A5|1981-09-30|

AT362524B|1981-05-25|

DE2714763A1|1977-10-06|

IT1115959B|1986-02-10|

JPS5715698B2|1982-04-01|

GB1544337A|1979-04-19|

ES460988A1|1978-05-01|

JPS52120896A|1977-10-11|

FR2346692B1|1982-04-23|

SE7703712L|1977-10-03|

AR212616A1|1978-08-15|

DE2714763B2|1980-07-10|

CA1085644A|1980-09-16|

ES457430A1|1978-03-01|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

DE608010C|1932-07-22|1935-01-15|Ernst Fischer Dr Ing|Centrifuge glass|

US2398737A|1943-02-19|1946-04-16|Robert L Elliot|Pipette and method of making same|

GB978743A|1960-05-25|1964-12-23|Nat Res Dev|Process for the preparation of an eosinophil-containing material and extracts thereof from blood|

US3437266A|1967-07-03|1969-04-08|Sondell Research & Dev Co|Centrifugal separation enhancement|

US3508653A|1967-11-17|1970-04-28|Charles M Coleman|Method and apparatus for fluid handling and separation|

US3513976A|1968-03-19|1970-05-26|William C James|Leukocyte flask and method of obtaining white cells from whole blood|

US3647070A|1970-06-11|1972-03-07|Technicon Corp|Method and apparatus for the provision of fluid interface barriers|

US3814248A|1971-09-07|1974-06-04|Corning Glass Works|Method and apparatus for fluid collection and/or partitioning|

US3898982A|1972-11-13|1975-08-12|Jintan Terumo Co|Capillary tube for blood examination|

GB1391053A|1972-02-27|1975-04-16|Sarstedt W|Device for the extraction of blood|

US4001122A|1973-08-22|1977-01-04|Telan Corporation|Method and device for separating blood components|

US3920557A|1974-02-27|1975-11-18|Becton Dickinson Co|Serum/plasma separator--beads-plus-adhesive type|

US3919085A|1974-02-27|1975-11-11|Becton Dickinson Co|Plasma separator assembly|

US3914985A|1974-03-29|1975-10-28|American Hospital Supply Corp|Centrifuging device and method|

US3981804A|1975-06-25|1976-09-21|Corning Glass Works|Apparatus for separating multiphase fluids|US4137755A|1976-09-20|1979-02-06|Wardlaw Stephen C|Material layer volume determination|

US4476016A|1976-10-06|1984-10-09|Kiyasu John Y|Heart attack screening method, apparatus and kit for same|

IT1103118B|1977-01-10|1985-10-14|Levine Robert A|DEVICE AND TECHNIQUE TO IMPROVE THE SEPARATION OF CELL LAYERS IN CENTRIFUGAL BLOOD SAMPLES|

US4156570A|1977-04-18|1979-05-29|Robert A. Levine|Apparatus and method for measuring white blood cell and platelet concentrations in blood|

SE7710076L|1977-09-08|1979-03-09|Ericson Curt|BLOOD SAMPLING CONTAINER|

US4190535A|1978-02-27|1980-02-26|Corning Glass Works|Means for separating lymphocytes and monocytes from anticoagulated blood|

CA1140212A|1978-10-02|1983-01-25|Roderick J. Flower|Method of and apparatus for monitoringplatelet aggregation and test cell for usein such method apparatus|

US4190328A|1978-12-01|1980-02-26|Levine Robert A|Process for detection of blood-borne parasites|

US4255256A|1978-12-13|1981-03-10|Antonio Ferrante|Medium for the separation of human blood leucocytes|

US4344560A|1979-11-02|1982-08-17|Asahi Kasei Kogyo Kabushiki Kaisha|Container, apparatus and method for separating platelets|

US4259012A|1979-11-19|1981-03-31|Wardlaw Stephen C|Blood count reader|

US4332785A|1980-04-09|1982-06-01|University Patents, Inc.|Immunoassay for measurement of reticulocytes, and immunoreactive reagents for use therein|

US4447547A|1980-04-09|1984-05-08|University Patents, Inc.|Immunoassay for measurement of reticulocytes, and immunoreactive reagents for use therein|

US4456000A|1981-08-17|1984-06-26|Angiomedics Corporation|Expandable occlusion apparatus|

SE425993B|1980-12-23|1982-11-29|Tesi Ab|PROCEDURE AND DEVICE FOR TIME-MARKING SEDIMENTATION PROCESSES|

US4409820A|1981-06-17|1983-10-18|Irwin Nash|Apparatus and method for use in quantitative analysis of a fluid suspension|

FR2508305B1|1981-06-25|1986-04-11|Slama Gerard|DEVICE FOR CAUSING A LITTLE BITE TO COLLECT A BLOOD DROP|

US4717660A|1984-01-26|1988-01-05|Becton, Dickinson And Company|Detection of bacteria by fluorescent staining in an expanded buffy coat|

US4594165A|1984-11-16|1986-06-10|Levine Robert A|Method of enhancing separation of abnormally light red cells from granulocytes in a centrifuged blood sample|

US4567754A|1985-03-29|1986-02-04|Wardlaw Stephen C|Measurement of small heavy constituent layer in stratified mixture|

US4695553A|1985-11-01|1987-09-22|Becton Dickinson And Co., Inc.|Method for increasing agglutination of groups of cells to produce improved cell layer interface in centrifuged blood sample using antibodies|

US4762798A|1985-12-31|1988-08-09|Marshall Diagnostics, Inc.|Device and method for determining a characteristic of a fluid sample|

US4823624A|1987-07-01|1989-04-25|Becton Dickinson & Company|Material layer volume determination with correction band|

US4774965A|1987-07-01|1988-10-04|Becton Dickinson And Co., Inc.|Material layer volume determination with correction band|

US4818386A|1987-10-08|1989-04-04|Becton, Dickinson And Company|Device for separating the components of a liquid sample having higher and lower specific gravities|

US4875364A|1988-03-21|1989-10-24|Levine Robert A|Method for measuring hemoglobin|

US4843869A|1988-03-21|1989-07-04|Levine Robert A|Method for measuring hemoglobin|

US5065768A|1988-09-13|1991-11-19|Safe-Tec Clinical Products, Inc.|Self-sealing fluid conduit and collection device|

US4953975A|1989-01-30|1990-09-04|Levine Robert A|Correction of material layer volume measurements|

CA2011099A1|1989-04-19|1990-10-19|Stephen C. Wardlaw|Determination of lymphocyte reactivity to specific antigens in blood|

CA2011100C|1989-05-24|1996-06-11|Stephen C. Wardlaw|Centrifuged material layer measurements taken in an evacuated tube|

US5132087A|1989-10-16|1992-07-21|Kristen L Manion|Apparatus for measuring blood constituent counts|

US5137832A|1991-01-02|1992-08-11|Becton Dickinson & Company|Quantification of fibrinogen in whole blood samples contained in a tube using a float to separate materials|

US5321975A|1991-10-04|1994-06-21|Levine Robert A|Differential erythrocyte counts|

US5252460A|1991-10-28|1993-10-12|Fiedler Paul N|In vitro detection of ova, parasites, and other formed elements in stool|

US5251474A|1992-01-16|1993-10-12|Wardlaw Stephen C|Centrifuged material layer measurement in an evacuated tube|

DK0557595T3|1992-02-25|1997-12-29|Robert A Levine|Target component assay|

US5342790A|1992-10-30|1994-08-30|Becton Dickinson And Company|Apparatus for indirect fluorescent assay of blood samples|

US5594164A|1994-07-12|1997-01-14|Bull; Brian S.|Method and apparatus for rapid determination of blood sedimentation rate|

US5736033A|1995-12-13|1998-04-07|Coleman; Charles M.|Separator float for blood collection tubes with water swellable material|

US5560830A|1994-12-13|1996-10-01|Coleman; Charles M.|Separator float and tubular body for blood collection and separation and method of use thereof|

US5707876A|1996-03-25|1998-01-13|Stephen C. Wardlaw|Method and apparatus for harvesting constituent layers from a centrifuged material mixture|

US5789259A|1996-09-27|1998-08-04|Robert A. Levine|Method and apparatus for mixing samples in a capillary tube|

US5776078A|1996-11-25|1998-07-07|Robert A. Levine|Cassette holder for capillary tube blood testing with integral sealing means|

US5743138A|1997-01-22|1998-04-28|Chartered Semiconductor Manufacturing Ltd.|Spirally fluted float|

US5888184A|1997-03-10|1999-03-30|Robert A. Levine|Method for rapid measurement of cell layers|

US5811303A|1997-04-01|1998-09-22|Streck Laboratories, Inc.|Quantitative buffy coat control composition|

AU9233698A|1997-11-22|1999-06-17|Robert A. Levine|Method for the detection, identification, enumeration and confirmation of circulating cancer cells and/or hematologic progenitor cells in whole blood|

US6197523B1|1997-11-24|2001-03-06|Robert A. Levine|Method for the detection, identification, enumeration and confirmation of circulating cancer and/or hematologic progenitor cells in whole blood|

US6911315B2|1997-11-24|2005-06-28|David L. Rimm|Method for the detection, identification, enumeration and confirmation of virally infected cells and other epitopically defined cells in whole blood|

US6030086A|1998-03-02|2000-02-29|Becton, Dickinson And Company|Flash tube reflector with arc guide|

US6120429A|1998-03-02|2000-09-19|Becton, Dickinson And Company|Method of using inertial tube indexer|

US6285450B1|1998-03-02|2001-09-04|Bradley S. Thomas|Blood centrifugation device with movable optical reader|

US6002474A|1998-03-02|1999-12-14|Becton Dickinson And Company|Method for using blood centrifugation device with movable optical reader|

US6080366A|1998-03-02|2000-06-27|Becton, Dickinson And Company|Disposable blood tube holder|

US6152868A|1998-03-02|2000-11-28|Becton, Dickinson And Company|Inertial tube indexer|

US6074883A|1998-03-02|2000-06-13|Becton, Dickinson And Company|Method for using disposable blood tube holder|

US5948686A|1998-03-07|1999-09-07|Robert A. Leuine|Method for performing blood cell counts|

US6153148A|1998-06-15|2000-11-28|Becton, Dickinson And Company|Centrifugal hematology disposable|

US6016696A|1998-09-25|2000-01-25|Lucent Technologies Inc.|Method for determining volume changes in viscous liquids|

US7947236B2|1999-12-03|2011-05-24|Becton, Dickinson And Company|Device for separating components of a fluid sample|

US7205157B2|2001-01-08|2007-04-17|Becton, Dickinson And Company|Method of separating cells from a sample|

DE10106362B4|2001-02-12|2005-03-17|Licht, Michael, Dipl.-Ing. |Apparatus and method for collecting aqueous fluid samples|

US8328024B2|2007-04-12|2012-12-11|Hanuman, Llc|Buoy suspension fractionation system|

US20030205538A1|2002-05-03|2003-11-06|Randel Dorian|Methods and apparatus for isolating platelets from blood|

US7992725B2|2002-05-03|2011-08-09|Biomet Biologics, Llc|Buoy suspension fractionation system|

US7845499B2|2002-05-24|2010-12-07|Biomet Biologics, Llc|Apparatus and method for separating and concentrating fluids containing multiple components|

US7832566B2|2002-05-24|2010-11-16|Biomet Biologics, Llc|Method and apparatus for separating and concentrating a component from a multi-component material including macroparticles|

US20060278588A1|2002-05-24|2006-12-14|Woodell-May Jennifer E|Apparatus and method for separating and concentrating fluids containing multiple components|

US7374678B2|2002-05-24|2008-05-20|Biomet Biologics, Inc.|Apparatus and method for separating and concentrating fluids containing multiple components|

US8567609B2|2006-05-25|2013-10-29|Biomet Biologics, Llc|Apparatus and method for separating and concentrating fluids containing multiple components|

AU2003249642A1|2002-05-24|2003-12-12|Biomet Manufacturing Corp.|Apparatus and method for separating and concentrating fluids containing multiple components|

US7074577B2|2002-10-03|2006-07-11|Battelle Memorial Institute|Buffy coat tube and float system and method|

US7220593B2|2002-10-03|2007-05-22|Battelle Memorial Institute|Buffy coat separator float system and method|

US6905612B2|2003-03-21|2005-06-14|Hanuman Llc|Plasma concentrate apparatus and method|

US20040182795A1|2003-03-21|2004-09-23|Randel Dorian|Apparatus and method for concentration of plasma from whole blood|

ES2426172T3|2005-02-07|2013-10-21|Hanuman Llc|Plasma concentrator device|

US7866485B2|2005-02-07|2011-01-11|Hanuman, Llc|Apparatus and method for preparing platelet rich plasma and concentrates thereof|

EP2910258B1|2005-02-07|2018-08-01|Hanuman LLC|Platelet rich plasma concentrate apparatus|

EP1848474B1|2005-02-07|2013-06-12|Hanuman LLC|Platelet rich plasma concentrate apparatus and method|

US7694828B2|2005-04-27|2010-04-13|Biomet Manufacturing Corp.|Method and apparatus for producing autologous clotting components|

US7771590B2|2005-08-23|2010-08-10|Biomet Manufacturing Corp.|Method and apparatus for collecting biological materials|

US8048297B2|2005-08-23|2011-11-01|Biomet Biologics, Llc|Method and apparatus for collecting biological materials|

US7806276B2|2007-04-12|2010-10-05|Hanuman, Llc|Buoy suspension fractionation system|

US7998696B2|2007-12-05|2011-08-16|Zyomyx, Inc.|Cell assay kit and method|

EP2620139B1|2008-02-27|2016-07-20|Biomet Biologics, LLC|Interleukin-1 receptor antagonist rich solutions|

US8337711B2|2008-02-29|2012-12-25|Biomet Biologics, Llc|System and process for separating a material|

US8012077B2|2008-05-23|2011-09-06|Biomet Biologics, Llc|Blood separating device|

AU2009274104B2|2008-07-21|2012-06-07|Becton, Dickinson And Company|Density phase separation device|

ES2754033T3|2008-07-21|2020-04-15|Becton Dickinson Co|Density phase separation device|

EP2517793B1|2008-07-21|2013-09-11|Becton, Dickinson and Company|Density phase separation device|

US8187475B2|2009-03-06|2012-05-29|Biomet Biologics, Llc|Method and apparatus for producing autologous thrombin|

US8313954B2|2009-04-03|2012-11-20|Biomet Biologics, Llc|All-in-one means of separating blood components|

ES2867676T3|2009-05-15|2021-10-20|Becton Dickinson Co|Density phase separation device|

US9011800B2|2009-07-16|2015-04-21|Biomet Biologics, Llc|Method and apparatus for separating biological materials|

US20110201045A1|2010-02-17|2011-08-18|Levine Joshua D|Method and apparatus for performing hematologic analysis using an array-imaging system for imaging and analysis of a centrifuged analysis tube|

US8591391B2|2010-04-12|2013-11-26|Biomet Biologics, Llc|Method and apparatus for separating a material|

CA2826571A1|2011-11-08|2013-05-16|Rarecyte, Inc.|Methods and systems for separating components of a suspension using a secondary liquid|

WO2013074138A1|2011-11-15|2013-05-23|Rarecyte, Inc.|Systems to control fluid flow in density-based fluid separation|

US9642956B2|2012-08-27|2017-05-09|Biomet Biologics, Llc|Apparatus and method for separating and concentrating fluids containing multiple components|

US10208095B2|2013-03-15|2019-02-19|Biomet Manufacturing, Llc|Methods for making cytokine compositions from tissues using non-centrifugal methods|

US9950035B2|2013-03-15|2018-04-24|Biomet Biologics, Llc|Methods and non-immunogenic compositions for treating inflammatory disorders|

US20140271589A1|2013-03-15|2014-09-18|Biomet Biologics, Llc|Treatment of collagen defects using protein solutions|

US10143725B2|2013-03-15|2018-12-04|Biomet Biologics, Llc|Treatment of pain using protein solutions|

US9895418B2|2013-03-15|2018-02-20|Biomet Biologics, Llc|Treatment of peripheral vascular disease using protein solutions|

US9550028B2|2014-05-06|2017-01-24|Biomet Biologics, LLC.|Single step desiccating bead-in-syringe concentrating device|

US9694359B2|2014-11-13|2017-07-04|Becton, Dickinson And Company|Mechanical separator for a biological fluid|

US9713810B2|2015-03-30|2017-07-25|Biomet Biologics, Llc|Cell washing plunger using centrifugal force|

US9757721B2|2015-05-11|2017-09-12|Biomet Biologics, Llc|Cell washing plunger using centrifugal force|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

US05/673,058|US4027660A|1976-04-02|1976-04-02|Material layer volume determination|

[返回顶部]