METHOD FOR AUTOMATICALLY DISTINGUISHING WHOLE BLOOD/PLASMA/NON-SUCTION BY MEANS OF REFLECTIVE PHOTOSENSOR

Abstract

A method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor in an automatic immunoassay device including a round cartridge which may simultaneously perform the centrifugation and automatic analysis of a blood sample and a tip which may be moved up, down, left and right based on the round cartridge, the method includes: installing the reflective photosensor below the round cartridge; mounting the tip above the round cartridge, and continuously measuring blood non-absorption data in a range including a position where the blood is absorbed by using the reflective photosensor, collecting the measured data and storing the collected data while the tip is raised; continuously measuring blood absorption data by using the reflective photosensor while the tip is lowered and absorbs the blood present in the range including the position where the blood is absorbed from the round cartridge; and determining whether a type of the blood is whole blood or blood plasma, or whether the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data.

Description

TECHNICAL FIELD

The present invention relates to a method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor, and more particularly, to a method of automatically distinguishing whether whole blood or blood plasma is absorbed or whether the whole blood or the blood plasma is not absorbed by using a reflective photosensor, the method being capable of accurately checking whether the whole blood or the blood plasma is absorbed or whether the whole blood or the blood plasma is not absorbed from a round cartridge into a pipette mounted on a tip of an automatic immunoassay device including the round cartridge which may simultaneously perform the centrifugation and automatic analysis of a blood sample and the tip which may be moved up, down, left and right based on the round cartridge.

BACKGROUND ART

In general, an immunoassay device may measure concentration of a specific biomarker protein in the blood plasma or serum of a human body.

The immunoassay device is not necessary to calibrate the measured concentration before outputting a result when directly using the blood plasma or serum as a measurement sample. However, when using whole blood as the measurement sample and analyzing the blood plasma or serum in the whole blood, the immunoassay device is necessary to correct the measured concentration by using a hematocrit of the measurement sample before outputting the result.

In general, a conventional immunoassay device may require centrifugation of the measurement sample separately performed in an external laboratory, or the manually input measured hematocrit and type (whole blood/blood plasma/serum) of the sample.

In this case, it may be necessary to separately input information on the measurement sample.

In addition, in order to solve this problem, a method has been proposed in which the hematocrit is optically measured to correct the result. However, it is impossible to generally use this method for all the immunoassay devices.

In addition, it may be inconvenient to separately input the information on the measurement sample.

That is, when using the sample of the whole blood, it is necessary to calculate and correct a ratio of a volume occupied by red blood cells to a total volume of the whole blood, i.e. the hematocrit, as a parameter to be considered when analyzing a substance included in a blood plasma component, and this parameter may significantly depend on age, climate, nutrition, illness and another factor. For example, a hematocrit of 40% may indicate that the red blood cells occupy 40% of the volume of the whole blood and the blood plasmas occupy 60% thereof. Therefore, when a volume of the hematocrit is increased in a patient's blood, a volume of the blood plasma may be decreased in the blood sample having a predetermined constant volume which is injected into the test device, and vice versa.

Only the blood plasma component may contain an analyte to be measured. Therefore, when a reaction mixture gets a smaller volume of the blood plasma component added thereto, the reaction mixture may have a reduced concentration of the substance to be measured therein, thus obtaining a smaller analytical value, and vice versa.

In any and every analysis of the concentration of the blood plasma substance in whole blood, it is necessary to perform a correction for a change in the hematocrit to obtain a true blood plasma concentration.

In order to omit this correction, it is possible to perform an analysis on serum or blood plasma in which the red blood cells are filtered or centrifuged in advance, which may increase the cost due to a complex design. In addition, most of the immunoassay devices may require the manual input of the whole blood, blood plasma or serum, which may not only be very cumbersome for an analyst but also may significantly reduce accuracy of the immunoassay if the analyst makes an error.

DISCLOSURE

Technical Problem

An exemplary embodiment of the present invention provides to a method of a method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor, the method being capable of accurately checking whether the whole blood or the blood plasma is absorbed or whether the whole blood or the blood plasma is not absorbed into a pipette mounted on a tip of an automatic immunoassay device including a round cartridge which may simultaneously perform the centrifugation and automatic analysis of a blood sample and the tip which may be moved up, down, left and right based on the round cartridge.

Technical Solution

According to an exemplary embodiment of the present invention, a method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor in an automatic immunoassay device including a round cartridge which may simultaneously perform the centrifugation and automatic analysis of a blood sample and a tip which may be moved up, down, left and right based on the round cartridge, the method includes: installing the reflective photosensor below the round cartridge; mounting the tip above the round cartridge, and continuously measuring blood non-absorption data in a range including a position where the blood is absorbed by using the reflective photosensor, collecting the measured data and storing the collected data while the tip is raised;

continuously measuring blood absorption data by using the reflective photosensor while the tip is lowered and absorbs the blood present in the range including the position where the blood is absorbed from the round cartridge; and determining whether a type of the blood is whole blood or blood plasma, or whether the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data.

ADVANTAGEOUS EFFECTS

As set forth above, the method of automatically distinguishing the absorption or non-absorption of the whole blood or the blood plasma by using the reflective photosensor according to an exemplary embodiment of the present invention may accurately check whether the whole blood or the blood plasma is absorbed or whether the whole blood or the blood plasma is not absorbed from the round cartridge into the pipette mounted on the tip of the automatic immunoassay device including the round cartridge which may simultaneously perform the centrifugation and automatic analysis of the blood sample and the tip which may be moved up, down, left and right based on the round cartridge.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view of an automatic immunoassay device including a tip which may be moved up, down, left and right based on a conventional round cartridge.

FIGS. 2 and 3 are a graph showing a method of determining whether a type of the blood is whole blood or blood plasma or whether the whole blood or the blood plasma is not absorbed, by comparing blood non-absorption data with blood absorption data in the automatic immunoassay device including the tip which may be moved up, down, left and right based on the conventional round cartridge, and a graph showing a determination result value obtained from the same tip used for one measurement.

FIG. 4 is a flowchart showing a method of comparing the blood non-absorption data with the blood absorption data in the automatic immunoassay device including the tip which may be moved up, down, left and right based on a round cartridge according to an exemplary embodiment of the present invention to determine whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed.

FIG. 5 is a side view showing an operation of the automatic immunoassay device including the tip which may be moved up, down, left and right based on the round cartridge according to an exemplary embodiment of the present invention.

FIG. 6 is a graph showing a method of determining whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed, by comparing the blood non-absorption data with the blood absorption data in the automatic immunoassay device including the tip which may be moved up, down, left and right based on the round cartridge according to an exemplary embodiment of the present invention.

FIGS. 7 to 10 are graphs showing whether the type of the blood is the whole blood or the blood plasma and a result value of the whole blood or blood plasma when the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data, obtained from the same tip used for one measurement, in the automatic immunoassay device including the tip which may be moved up, down, left and right based on the round cartridge according to an exemplary embodiment of the present invention.

FIGS. 11 and 12 are graphs showing whether the type of the blood is the whole blood or the blood plasma and the result value of the whole blood or blood plasma when the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data, obtained from two different tips used for one measurement, in the automatic immunoassay device including the tip which may be moved up, down, left and right based on the round cartridge according to an exemplary embodiment of the present invention.

MODE FOR INVENTION

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains may easily practice the present invention. The present invention may be modified in various different forms, and is not limited to embodiments provided in the present specification. In addition, in the drawings, portions unrelated to the description are omitted to clearly describe the present invention, and similar portions are denoted by similar reference numerals throughout the specification.

In the specification, unless explicitly described to the contrary,“including” any component will be understood to imply the inclusion of other components rather than the exclusion of any other components. In addition, a term “part,” “module,” “device” or the like, described in the specification may indicate a unit of processing at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software.

Hereinafter, the description describes an automatic analysis device including a cartridge capable of performing the centrifugation and automatic analysis of a blood sample, according to an exemplary embodiment of the present invention, in detail with reference to the attached drawing.

In order to solve problems of the prior art, as shown in FIG. 1, Korean Patent Publication No. 10-1970790, entitled “Method and apparatus with improved accuracy”, which is filed and registered by the same applicant, shows an automatic analysis device 1 including a cartridge 100 capable of performing the centrifugation and automatic analysis of the blood sample, in which the cartridge 100 capable of performing the centrifugation and automatic analysis of the blood is installed in a cartridge accommodation housing 30 by reciprocating a main frame 10 disposed at a bottom of a cartridge accommodation housing 30 to an X-axis transfer unit 20 in an X-axis direction, a sample is injected into the cartridge 100 by moving a tip 61 by a tip elevation unit 60 disposed at an upper portion of the device 1, the cartridge is rotated by a rotary drive unit 50 disposed at a lower portion of the device 1 to centrifuge whole blood or rotated to repeatedly absorb/discharge a reagent, and an analysis process is performed by using a measurement unit 70.

Here, the main frame 10 may further include a reflective photosensor 80 accommodated in the cartridge accommodation housing 30 and automatically measuring, from the tip 61, whether a type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed. The reflective photosensor 80 may include a light source 81 and a light receiving element 83. The light source 81 may preferably be a long and thin light emitting diode (LED) disposed in an axial direction of the cartridge 100, and the light receiving element 83 may preferably be a charge coupled device (CCD) linear image sensor in which the plurality of light receiving elements are arranged in one row in the axial direction. The light receiving element 83 may receive light reflected from the light source 81 on a well surface of the cartridge 100.

Here, as shown in FIGS. 2 to 4, when the tip 61 reaches a height of 100 steps, which is half of a total height of 200 steps, i.e., when the tip 61 reaches its fixed point, it is possible to irradiate light from the light source 81 of the reflective photosensor 80, and read an output value of the light receiving sensor 83 reflected from a detected substance. It is then possible to compare a result value obtained from the same tip 61 used for one measurement or different tips 61, with a correction value of whole blood (wb) or the blood plasma to determine whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is absorbed.

However, the above-described method of reading the output value of the reflective photo sensor 80 at the fixed point of the tip 61 by using the sensor and comparing the output values of the whole blood and blood plasma with their correction values to make the determination may be difficult to accurately distinguish the values from each other due to deviation in device performance of the light receiving sensor 83 when using the different light receiving sensor 83, as shown in FIG. 3 and Table 1, and may be unable to accurately distinguish the two values from each other because the obtained output values may have an insufficient margin therebetween.

TABLE 1
Sensor no.	Wb absorbed	Plasma absorbed
1	2221	2274
2	1862	2202
3	1840	2044
4	2092	2679
5	2092	2422
6	1906	2291

As shown in Table 1 and FIG. 3, the light receiving sensors 83, i.e. sensor nos. 1, 2, 3, 4, 5 and 6, may each have a higher measurement value obtained when the whole blood (wb) is absorbed than a measurement value obtained when the blood plasma is absorbed. However, some sensors may show the measurement value of the whole blood (wb) is the same as the measurement value of the blood plasma (Blood plasma). In this case, the two values may not be clearly distinguished from each other.

In addition, each correction value of the two measurement values is necessary to be pre-determined for performing one measurement, depending on whether the type of the blood is the whole blood or the blood plasma whenever measuring the whole blood or the blood plasma is not absorbed into the tip 61.

In addition, the tip is necessary to be replaced for every measurement, and the measurement value may thus also be changed.

Hereinafter, the description describes a method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor according to an exemplary embodiment of the present invention in detail with reference to FIGS. 4 and 5.

FIG. 4 is a flowchart showing a method of comparing the blood non-absorption data with blood absorption data in the automatic immunoassay device including the tip which may be moved up, down, left and right based on a round cartridge according to an exemplary embodiment of the present invention to determine whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed; and FIG. 5 is a side view showing an operation of the automatic immunoassay device including the tip which may be moved up, down, left and right based on the round cartridge according to an exemplary embodiment of the present invention.

As shown in FIGS. 4 and 5, the method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor according to an exemplary embodiment of the present invention may provide a constant measurement value regardless of the device performance of the light receiving sensor 83, may clearly distinguish the measurement values of the whole blood and blood plasma because the difference between the measurement values of the whole blood and blood plasma is significant, and may have no need to set the respective correction values thereof in advance based on whether the whole blood or the blood plasma is absorbed or not absorbed.

The method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor according to an exemplary embodiment of the present invention, which is improved for this purpose, in the automatic immunoassay device 1 including the round cartridge 100 which may simultaneously perform the centrifugation and automatic analysis of the blood sample and the tip which may be moved up, down, left and right based on the round cartridge, may include: installing the reflective photosensor 80 below the round cartridge 100 and mounting the tip 61 above the round cartridge 100 (S10), and continuously measuring the blood non-absorption data in a range including a position where the blood is absorbed by using the reflective photosensor, collecting the measured data and storing the collected data while the tip 61 is raised (S20).

The method may include continuously measuring the blood absorption data by using the reflective photosensor while the tip is lowered and absorbs the blood present in the range including the position where the blood is absorbed from the round cartridge, collecting the measured data and storing the collected data (S30).

The method may include determining whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data (S40).

Here, the light source 81 of the reflective photosensor 80 may be the long and thin light emitting diode (LED) disposed below the cartridge 100 in the axial direction of the cartridge 100, and the light receiving element 83 may be the charge coupled device (CCD) linear image sensor disposed opposite to the light source 81, and installed in one row below the cartridge 100 in the axial direction of the cartridge 100.

In order to determine whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data, several measurements may be continuously performed to measure whether the whole blood or the blood plasma is not absorbed into the same tip 61 used for one measurement, whether the whole blood or the blood plasma is not absorbed into at least two or more different tips 61 used for different measurements, and whether the whole blood is absorbed into the tip 61 and whether the blood plasma is absorbed into the tip 61.

In order to determine whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data, the method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor according to an exemplary embodiment of the present invention may use a slope of data obtained from the continuous measurements of the blood in a specific section.

Therefore, it is possible to reduce the deviation by using the slope of the data obtained from the continuous measurements of the blood rather than one fixed measurement value.

As shown in FIG. 5, the slope may be a relative ratio of the measurement value of the whole blood or blood plasma obtained by using the reflective photosensor 80 to the height of the tip 61.

The specific section may be a section including first and second inflection points of the values obtained from the continuous measurements of whether the whole blood (wb) and the (blood) plasma by using the reflective photosensor 80, i.e., the point at which a difference between the values obtained from the continuous measurements of the whole blood (wb) and the (blood) plasma by using the reflective photosensor 80 begins to occur and the point at which the slope of the values obtained from the continuous measurements of the whole blood (wb) and the (blood) plasma by using the reflective photosensor 80 has a maximum value.

In the specific section, the tip 61 may be disposed at a height of 10 steps or more and 46 steps or less when the total height is 200 steps, and 500 to 700 may be the maximum value of the difference between the measurement values of the whole blood and the blood plasma obtained by using the reflective photosensor.

Hereinafter, referring to FIGS. 7 through 12 and Tables 1-2 and 2-2, the description describes that the method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor according to an exemplary embodiment of the present invention may provide the constant measurement value regardless of the device performance of the light receiving sensor 83, may clearly distinguish the measurement values of the whole blood and blood plasma because the difference between the measurement values of the whole blood and blood plasma is significant, and may have no need to set the respective correction values thereof in advance based on whether the whole blood or the blood plasma is absorbed or not absorbed.

FIGS. 7 to 10 are graphs showing whether the type of blood is the whole blood or the blood plasma and a result value of the whole blood or the blood plasma when the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data, obtained from the same tip used for one measurement, in the automatic immunoassay device including the tip which may be moved up, down, left and right based on the round cartridge according to an exemplary embodiment of the present invention; and FIGS. 11 and 12 are graphs showing whether the type of the blood is the whole blood or the blood plasma and the result value of the whole blood or the blood plasma when the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data, obtained from two different tips used for one measurement, in the automatic immunoassay device including the tip which may be moved up, down, left and right based on the round cartridge according to an exemplary embodiment of the present invention.

As shown in FIGS. 7 to 10, according to the method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor according to an exemplary embodiment of the present invention, the values continuously measured by the four light receiving sensors 83, i.e. sensors M1, M2, M3 and M4, and the graphs of the values all show the same pattern.

That is, the method may provide the constant measurement value regardless of the device performance of the light receiving sensor 83, and may clearly distinguish the measurement values of the whole blood and blood plasma because the difference between the measurement values of the whole blood and blood plasma is significant.

TABLE 2-1
	M1	M2	M3	M4
	tip	plsam	wb	tip2	tip	plsam	wb	tip2	tip	plsam	wb	tip2	tip	wb	wb	tip2
0	2164	2122	2123	2155	2074	2043	2045	2077	2204	2151	2120	2207	2270	2215	2206	2274
1	2163	2118	2125	2161	2071	2042	2046	2076	2204	2153	2120	2205	2270	2208	2206	2276
2	2165	2122	2123	2162	2069	2042	2045	2075	2205	2153	2122	2206	2269	2210	2206	2274
3	2164	2121	2123	2161	2070	2043	2046	2076	2204	2150	2122	2207	2270	2209	2207	2274
4	2168	2123	2122	2163	2070	2040	2047	2075	2204	2149	2123	2206	2268	2207	2204	2273
5	2160	2122	2122	2164	2067	2043	2046	2074	2201	2151	2123	2206	2270	2207	2202	2274
6	2166	2121	2120	2165	2067	2043	2044	2077	2203	2149	2127	2207	2269	2203	2200	2277
7	2166	2122	2119	2166	2069	2042	2045	2077	2201	2142	2128	2203	2270	2202	2295	2274
8	2168	2218	2117	2166	2068	2044	2046	2075	2203	2146	2130	2207	2271	2199	2191	2274
9	2166	2118	2108	2164	2069	2040	2044	2074	2203	2144	2128	2207	2221	2195	2181	2274
10	2168	2115	2103	2161	2071	2041	2041	2075	2202	2137	2127	2204	2273	2186	2177	2276
11	2168	2108	2091	2159	2070	2038	2036	2073	2201	2136	2124	2207	2271	2182	2159	2275
12	2167	2102	2071	2157	2071	2031	2030	2074	2201	2131	2116	2209	2271	2170	2139	2277
13	2169	2100	2070	2159	2069	2024	2017	2075	2200	2125	2107	2213	2271	2186	2128	2276
14	2169	2090	2039	2160	2070	2018	2011	2075	2199	2123	2100	2217	2273	2151	2108	2276
15	2171	2086	2021	2162	2069	2009	2050	2075	2199	2118	2084	2220	2272	2144	2090	2277
16	2169	2082	2012	21	2068	2003	1986	2074	2198	2115	2062	2220	2271	2141	2081	2273
17	2169	2083	1997	2162	2086	2002	1978	2072	2197	2114	2056	2220	2267	2145	2065	2274
18	2167	2087	1985	2162	2068	2003	1968	2071	2197	2115	2031	2214	2265	2155	2052	2272
19	2166	2103	1978	2163	2065	2010	1958	2072	2196	2122	2013	2212	2264	2175	2046	2270
20	2166	2132	1970	2162	2065	2016	1952	2072	2194	2128	2007	2211	226	2184	2036	2268
21	2166	2151	1967	2164	2066	2031	1945	2071	2195	2146	1994	2207	2259	2208	2027	2267
22	216	2194	1965	2165	2064	2053	1938	2069	2193	2175	1987	2205	2261	2233	2021	2265
23	2167	2239	1959	2164	2065	2066	1936	2068	2192	2190	1990	2203	2259	2246	2016	2265
24	2165	2267	1956	2168	2063	2095	1933	2068	2194	2225	1975	2201	2260	2272	2009	2265
25	2168	2314	1953	2167	2065	2125	1930	2068	2192	2263	1969	2200	2262	2299	2007	2267
26	2168	2358	1950	2169	2061	2141	1928	2067	2191	2280	1965	2200	2261	2309	2002	2266
27	2168	2379	1945	2168	2061	2173	1924	2065	2193	2322	1957	2200	2261	2330	1996	2264
28	2167	2418	1944	2170	2050	2206	1922	2007	2191	2356	1955	2196	2258	3247	1994	2264
29	2166	2453	1940	2167	2058	2222	1921	2065	2190	2373	1951	2195	2256	2354	1991	2287
30	2165	2472	1939	2169	2057	2251	1919	2062	2189	2403	1949	2194	2251	2371	1986	2256
31	2164	2503	1939	2166	2058	2778	1918	2064	2188	2427	1944	2191	2251	2374	1984	2260
32	2162	2531	1939	2165	2060	2287	1916	2062	2186	2439	1946	2190	2251	2377	1987	2255
33	2162	2544	1940	2166	2057	2307	1917	2063	2189	2458	1945	2190	2245	2382	1985	2257
34	2164	2562	1940	2168	2058	2321	1915	2064	2191	2473	1946	2193	2251	2384	1982	2257
35	2161	2580	1945	2164	2059	2328	1914	2064	2191	2478	1948	2197	2253	2389	1990	2260
36	2162	2582	1946	2166	2061	2334	1917	2063	2192	2487	1949	2193	2253	2391	1993	2258
37	2163	2592	1946	2164	2060	2339	1919	2066	2190	2490	1953	2197	2254	2390	1994	2257
38	2165	2602	1950	2168	2060	2341	1919	2063	2193	2493	1955	2197	2253	2390	1999	2259
39	2165	2602	1955	2169	2058	2340	1918	2064	2194	2493	1951	2196	2253	2389	2002	2257
40	2164	2606	1954	2170	2059	2340	1920	2064	2194	2495	1956	2195	2251	2386	2000	2258
41	2164	2607	1957	2168	2058	2336	1921	2062	2196	2493	1958	2198	2250	2387	2005	2257
42	2165	2604	1960	2169	2059	2333	1922	2063	2196	2491	1960	2196	2248	2381	2006	2255
43	2164	2603	1957	2168	2059	2327	1924	2061	2197	2487	1963	2197	2249	2379	2008	2254
44	2164	2601	1963	2175	2060	2326	1924	2062	2193	2483	1964	2197	2249	2378	2011	2255
45	2167	2600	1963	2169	2061	2319	1924	2063	2196	2478	1965	2199	2249	2374	2013	2254
46	2166	2595	1965	2169	2061	2313	1926	2061	2198	2475	1967	2196	2250	2372	2015	2255
47	2169	2592	2168	2168	2060	2309	1923	2062	2196	2470	1968	2196	2251	2373	2018	2256
48	2169	2588	1968	2167	2060	2304	1927	2063	2195	2463	1971	2196	2253	2371	2022	2256
49	2167	2588	1967	2165	2061	2302	1926	2060	2193	2464	1972	2192	2256	2370	2024	2260
indicates data missing or illegible when filed

TABLE 2-2
50	2167	2577	1968	2164	2060	2296	1928	2060	2193	2459	1974	2189	2255	2369	2027	2262
51	2167	2572	1968	2163	2060	2290	1929	2057	2194	2455	1975	2184	2254	2368	2028	2261
52	2167	2562	1969	2163	2062	2286	1931	2058	2191	2449	1976	2182	2258	2366	2026	2258
53	2166	2560	1969	2162	2062	2283	1930	2060	2190	2446	1978	2180	2259	2367	2030	2263
54	2166	2554	1969	2164	2062	2278	1932	2056	2189	2437	1978	2177	2260	2362	2031	2262
55	2168	2545	1971	2161	2061	2274	1933	2058	2189	2433	1981	2176	2259	2357	2034	2262
56	2167	2541	1971	2164	2061	2271	1933	2058	2190	2430	1980	2177	2258	2360	2036	2216
57	2170	2535	1971	2162	2060	2266	1933	2053	2189	2425	1984	2175	2260	2357	2035	2261
58	2168	2527	1971	2161	2062	2262	1937	2054	2190	2420	1986	2175	2257	2352	2035	2252
59	2172	2519	1973	2160	2063	2261	1936	2052	2187	2418	1988	2174	2260	2353	2038	2260
60	2170	2515	1975	2162	2062	2256	1937	2053	2187	2412	1992	2172	2257	2350	2041	2261
61	2170	2512	1975	2164	2062	2251	1938	2052	2186	2407	1992	2168	2258	2350	2041	2260
62	2171	2501	1974	2162	2065	2250	1938	2052	2184	2485	1992	2166	2258	2350	2045	2261
63	2173	2497	1976	2165	2063	2246	1940	2054	2184	2400	1955	2166	2261	2352	2049	2264
64	2173	2491	1977	2164	2063	2243	1942	2052	2184	2394	1995	2163	2262	2349	2050	2266
65	2173	2486	1980	2165	2065	2240	1940	2052	2183	2391	1996	2163	2266	2350	2055	2267
66	2175	2482	1979	2163	2066	2231	1944	2054	2183	2386	1996	2162	2267	2351	2058	2270
67	2174	2475	1979	2161	2066	2231	1942	2054	2182	2379	1996	2159	2269	2349	2060	2272
68	2175	2470	1979	2159	2089	2231	1941	2052	2181	2377	1997	2159	2269	2351	2063	2273
69	2176	2467	1982	2161	2067	2228	1946	2053	2180	2372	1995	2153	2271	2349	2067	2276
70	2177	2463	1985	2060	2070	2226	1948	2055	2178	2364	1993	2151	2275	2347	2068	2276
71	2176	2456	1983	2163	2068	2224	1949	2054	2177	2363	1994	2148	2275	2347	2070	2279
72	2177	2452	1984	2158	2070	2222	1951	2055	2177	2358	1994	2147	2276	2344	2072	2281
73	2176	2446	1983	2155	2073	2219	1951	2054	2177	2352	1994	2144	2275	2343	2073	2282
74	2175	2440	1988	2154	2074	2216	1952	2057	2177	2351	1995	2144	2279	2342	2076	2278
75	2177	2437	1987	2156	2074	2214	1954	2057	2177	2346	1995	2143	2282	2344	2080	2286
76	2177	2430	1990	2154	2075	2210	1956	2060	2177	2343	1996	2143	2284	2343	2081	2289
77	2178	2424	1989	2155	2078	2210	1954	2060	2180	2343	1995	2143	2286	2343	2086	2291
78	2179	2419	1991	2154	2080	2207	1959	2061	2176	2338	1998	2144	2288	2344	2089	2293
79	2176	2411	1991	2163	2079	2206	1962	2063	2176	2335	1998	2147	2290	2345	2099	2295
80	2177	2407	1989	2155	2082	2206	1961	2064	2176	2334	1998	2148	2290	2344	2094	2294
81	2177	2404	1991	2156	2081	2203	1963	2065	2176	2332	1999	2146	2291	2345	2094	2295
82	2181	2399	1992	2153	2080	2200	1965	2066	2173	2327	1999	2145	2293	2344	2097	2294
83	2175	2394	1990	2153	2084	2195	1965	2068	2172	2325	2000	2145	2295	2345	2100	2292
84	2175	2396	1993	2153	2085	2199	1965	2069	2172	2327	1999	2144	2295	2347	2101	2294
85	2177	2387	1993	2153	2087	2195	1969	2069	2172	2319	2001	2143	2297	2347	2103	2293/
86	2177	2388	1996	2155	2086	2197	1969	2071	2172	2318	1999	2148	2300	2348	2107	2293
87	2182	2383	1997	2154	2087	2193	1971	2073	2171	2315	2002	2146	2302	2350	2111	2295
88	2179	2381	1996	2155	2088	2194	1971	2074	2169	2317	2002	2147	2305	2352	2114	2295
89	2183	2378	2000	2157	2091	2192	1975	2075	2173	2316	2003	2148	2308	2352	2117	2294
90	2181	2375	2002	2161	2092	2191	1977	2076	2173	2314	2009	2147	2310	2352	2122	2295
91	2181	2373	2002	2156	2093	2192	1979	2078	2173	2310	2004	2147	2312	2354	2124	2298
92	2184	2373	2005	2158	2096	2192	1979	2081	2167	2309	1999	2148	2313	2354	2126	2297
93	2184	2372	2007	2161	2095	2188	1981	2081	2170	2307	2005	2144	2316	2355	2134	2299
94	2187	2371	2006	2158	2100	2188	1985	2082	2168	2304	2006	2146	2317	2355	2133	2302
95	2187	2365	2009	2160	2099	2187	1984	2079	2168	2300	2006	2145	2319	2358	2139	2302
96	2187	2364	2008	2158	2101	2185	1987	2081	2167	2299	2006	2142	2321	2359	2142	2303
97	2188	2362	2009	2160	2103	2186	1989	2086	2166	2254	2007	2142	2323	2357	2145	2307
98	2190	2360	2012	2162	2105	2186	1991	2084	2166	2296	2007	2144	2325	2361	2149	2307
99	2192	2359	2013	2162	2105	2185	1989	2089	2165	2293	2007	2143	2327	2362	2151	2310

In addition, as shown in FIGS. 11 and 12, and Tables 3-1 and 3-1, it may be seen that a relative value may be used to analyze and determine the pattern because the different tips 61 have the measurement values slightly different from each other, but show the same pattern when analyzing whether the sample is the whole blood or the blood plasma or analyzing the measurement value of the whole blood or blood plasma when the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data obtained from the different two tips used for one measurement by using the same reflective photosensor 80, in the automatic immunoassay device including the tip which may be moved up, down, left and right based on the round cartridge according to an exemplary embodiment of the present invention.

TABLE 3-1
Tip1	Tip 2
	tip	plsam	wb	tip2	tip	plsam	wb	tip2
0	2066	2038	2018	2068	2104	2074	2061	2104
1	2067	2035	2018	2068	2105	2074	2062	2103
2	2071	2040	2016	2065	2103	2073	2059	2103
3	2068	2039	2023	2067	2107	2074	2061	2103
4	2069	2038	2015	2067	2104	2073	2063	2106
5	2068	2037	2015	2066	2104	2072	2059	2104
6	2067	2037	2009	2065	2106	2071	2057	2105
7	2069	2033	2001	2066	2105	2071	2056	2103
8	2067	2029	1996	2067	2104	2070	2050	2107
9	2067	2024	1986	2066	2101	2068	2041	2104
10	2068	2021	1969	2067	2105	2064	2036	2102
11	2069	2014	1962	2066	2107	2065	2026	2104
12	2069	2007	1945	2065	2106	2057	2014	2106
13	2068	2007	1928	2064	2107	2054	2000	2105
14	2067	2006	1918	2066	2111	2051	1988	2105
15	2066	2013	1906	2067	2109	2045	1980	2107
16	2057	2017	1892	2063	2113	2041	1963	2109
17	2068	2033	1886	2066	2111	2042	1957	2111
18	2066	2060	1874	2063	2113	2041	1944	2109
19	2065	2072	1865	2065	2114	2046	1993	2113
20	2066	2103	1861	2066	2113	2052	1921	2110
21	2067	2137	1851	2064	2113	2061	1916	2110
22	2065	2154	1845	2066	2111	2079	1904	2109
23	2072	2190	1840	2062	2110	2089	1991	2105
24	2067	2226	1836	2063	2107	2110	1890	2107
25	2067	2246	1826	2063	2109	2131	1884	2103
26	2066	2280	1826	2066	2109	2144	1882	2104
27	2068	2312	1822	2067	2110	2166	1873	2102
28	2068	2328	1818	2068	2106	2189	1870	2104
29	2072	2355	1815	2069	2108	2202	1867	2104
30	2073	2375	1814	2071	2112	2224	1864	2100
31	2073	2386	1812	2072	2111	2242	1864	2106
32	2079	2397	1811	2071	2113	2251	1866	2105
33	2076	2406	1810	2072	2114	2263	1864	2105
34	2075	2410	1812	2072	2115	2271	1864	2105
35	2077	2414	1812	2074	2117	2275	1868	2108
36	2077	2416	1811	2071	2118	2281	1866	2107
37	2079	2419	1815	2072	2119	2285	1868	2110
38	2079	2416	1814	2072	2116	2287	1872	2108
39	2081	2416	1815	2073	2121	2290	1870	2109
40	2082	2413	1817	2074	2127	2296	1873	2109
41	2082	2413	1817	2072	2127	2294	1876	2114
42	2082	2407	1819	2073	2130	2293	1879	2112
43	2082	2409	1821	2076	2132	2293	1884	2114
44	2084	2403	1823	2073	2132	2294	1883	2116
45	2086	2404	1824	2076	2136	2296	1882	2117
46	2086	2399	1827	2077	2138	2295	1889	2119
47	2089	2394	1830	2076	2141	2292	1891	2122
48	2092	2392	1830	2079	2142	2295	1895	2125
49	2092	2391	1832	2083	2146	2295	1900	2125
50	2097	2386	1832	2080	2147	2297	1901	2127

TABLE 3-2
51	2095	2336	1835	2079	2150	2293	1904	2130
52	2097	2383	1836	2082	2153	2296	1908	2131
53	2096	2382	1839	2080	2158	2296	1910	2137
54	2099	2377	1840	2080	2159	2296	1914	2138
55	2097	2378	1836	2082	2166	2294	1918	2140
56	2098	2372	1843	2082	2167	2296	1917	2144
57	2098	2368	1845	2084	2173	2295	1925	2148
58	2101	2355	1849	2085	2175	2294	1932	2151
59	2106	2363	1851	2087	2182	2296	1936	2156
60	2108	2359	1856	2088	2183	2295	1939	2158
61	2112	2356	1859	2091	2188	2294	1945	2162
62	2112	2352	1859	2093	2194	2294	1948	2168
63	2118	2350	1863	2096	2196	2293	1956	2172
64	2119	2346	1868	2097	2201	2294	1960	2172
65	2125	2340	1871	2099	2210	2293	1964	2179
66	2127	2339	1874	2101	2208	2294	1970	2186
67	2129	2346	1877	2105	2215	2293	1974	2188
68	2134	2335	1879	2107	2218	2294	1977	2188
69	2139	2334	1884	2109	2222	2293	1983	2193
70	2137	2334	1886	2112	2224	2294	1989	2194
71	2143	2330	1889	2110	2230	2295	1991	2199
72	2146	2327	1894	2117	2233	2293	1996	2202
73	2146	2327	1895	2119	2236	2292	2001	2205
74	2150	2328	1895	2119	2242	2293	2005	2207
75	2152	2322	1900	2121	2241	2295	2007	2213
76	2153	2323	1905	2122	2244	2294	2015	2214
77	2158	2318	1906	2125	2251	2297	2016	2219
78	2159	2319	1912	2125	2253	2296	2023	2221
79	2160	2317	1912	2130	2256	2296	2030	2226
80	2165	2316	1915	2130	2262	2298	2029	2230
81	2166	2314	1917	2132	2268	2297	2036	2234
82	2169	2316	1923	2136	2273	2301	2043	2236
83	2174	2312	1926	2137	2277	2302	2048	2241
84	2179	2313	1932	2142	2281	2302	2054	2247
85	2183	2309	1936	2145	2287	2306	2062	2247
86	2183	2307	1937	2146	2293	2310	2066	2255
87	2188	2306	1944	2152	2294	2308	2074	2260
88	2189	2307	1948	2154	2304	2312	2083	2266
89	2194	2303	1951	2155	2309	2313	2084	2271
90	2200	2304	1959	2164	2313	2316	2092	2274
91	2203	2305	1963	2169	2321	2319	2098	2280
92	2206	2309	1965	2170	2324	2323	2102	2286
93	2211	2308	1971	2177	2329	2320	2108	2295
94	2215	2305	1977	2177	2337	2324	2115	2296
95	2217	2301	1973	2179	2339	2328	2119	2605
96	2224	2307	1985	2182	2341	2330	2124	2310
97	2224	2307	1987	2185	2347	2332	2131	2311
98	2231	2304	1998	2186	2351	2334	2133	2316
99	2233	2306	1995	2190	2353	2336	2143	2320

INDUSTRIAL APPLICABILITY

The method of automatically distinguishing the absorption or non-absorption of the whole blood or the blood plasma by using the reflective photosensor according to an exemplary embodiment of the present invention may accurately check whether the whole blood or the blood plasma is absorbed or whether the whole blood or the blood plasma is not absorbed from the round cartridge into the pipette mounted on the tip of the automatic immunoassay device including the round cartridge which may simultaneously perform the centrifugation and automatic analysis of the blood sample and the tip which may be moved up, down, left and right based on the round cartridge.

Claims

1. A method of automatically distinguishing absorption or non-absorption of whole blood or blood plasma by using a reflective photosensor in an automatic immunoassay device including a round cartridge which may simultaneously perform the centrifugation and automatic analysis of a blood sample and a tip which may be moved up, down, left and right based on the round cartridge, the method comprising: installing the reflective photosensor below the round cartridge;mounting the tip above the round cartridge, and continuously measuring blood non-absorption data in a range including a position where the blood is absorbed by using the reflective photosensor, collecting the measured data and storing the collected data while the tip is raised;continuously measuring blood absorption data by using the reflective photosensor while the tip is lowered and absorbs the blood present in the range including the position where the blood is absorbed from the round cartridge; anddetermining whether a type of the blood is whole blood or blood plasma, or whether the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data.

2. The method of claim 1, wherein the reflective photosensor includes a light source which is a long and thin light emitting diode (LED) disposed below the round cartridge in an axial direction of the cartridge, and a light receiving element which is a charge coupled device (CCD) linear image sensor opposite to the light source, and installed in one row below the cartridge in the axial direction of the cartridge.

3. The method of claim 1, wherein the determining of whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data includes performing the measurements of whether the whole blood or the blood plasma is not absorbed into the tip or at least two or more different tips, whether the whole blood is absorbed into the tip, and whether the blood plasma is absorbed into the tip.

4. The method of claim 3, wherein in the determining of whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data, the determination is made by a slope, which is a ratio of the measurement value of the whole blood or blood plasma obtained by using the reflective photosensor to a height of the tip.

5. The method of claim 4, wherein in the determining of whether the type of the blood is the whole blood or the blood plasma, or whether the whole blood or the blood plasma is not absorbed by comparing the blood non-absorption data with the blood absorption data,the determination is made by the slope of data obtained from the continuous measurements of the blood in a section includinga point at which a difference between values obtained from the continuous measurements of the whole blood (wb) and the (blood) plasma by using the reflective photosensor begins to occur anda point at which the slope of the values obtained from the continuous measurements of the whole blood (wb) and the (blood) plasma by using the reflective photosensor has a maximum value.

6. The method of claim 5, wherein the tip in the section has a height of 10 steps or more and 46 steps or less when a total height is 200 steps.

7. The method of claim 5, wherein 500 to 700 is a maximum value of a difference between the measurement values of the whole blood and the blood plasma obtained by using the reflective photosensor.