APPARATUS FOR DETECTING ANALYTE IN A LIQUID SAMPLE AND METHOD THEREOF
The present invention provides an apparatus for detecting the presence or absence of an analyte in liquid sample, including: a collection chamber, including an opening for collecting a liquid sample; a testing element for testing the analyte in liquid sample; and a cover for covering the opening of the collection chamber; wherein the apparatus further includes a prompting device for prompting if the cover is covered to a specified location, and the prompting device shall at least includes a first element and a second element, the first element is in contact with the second element, wherein one element vibrates to produce a sound. In some preferred ways, the second element produces friction with the first element, to cause one of the elements to generate vibrations. The apparatus in the present invention can allow the prompting sound to be clear and loud.
The present invention relates to an apparatus for detecting analyte in a liquid sample and method thereof.
BACKGROUNDThe following background art is provided to assist readers in understanding the present invention rather than a prior art.
At present, illegal drug abuse has become a recognized and increasingly worsening social problem. In 2003, the survey conducted by the US Department of Health and Human Services revealed that about 19.5 million Americans or 8.2% of people over the age of 12 are taking illegal drugs. “Recent use of illegal drugs” refers to the use of an illegal drug within one month before the US Department of Health and Human Services conducted a survey. Cannabis is found to be the most commonly used illegal drugs, accounting for 6.2% (14.6 million). Now about 2.30 million people (1.0%) are using cocaine, 604,000 people use Crack, and 1 million people are using hallucinogens, and it is estimated that 119,000 people are using heroin. With the development of the times, many new drugs are emerging, and it has become one of the world's important social problems.
In order to fight against the drug abuse monitor this social problem, the drug testing has become a standard test procedure in various industries such as hiring, education, sports, and law enforcement, etc. To promote this effort, the drug testing industry has formed. This industry has provided a wide range of drug testing products. The urine sample collection cup for sample analysis is a classic testing product. These devices may be complex, difficult or dirty for users, or may cause the problem of adulteration in the sample to conceal the use of illegal drugs recently. In addition, the urine samples cannot be collected in some cases, for example, on the roadside or in the public places.
It has become a very common method to collect liquid samples such as urine using a detection apparatus and determine if there is specific analyte (such as drugs and/or their metabolites, or disease-related markers). For this kind of device, usually the samples are required to be collected in the sample container, and relevant technicians insert a test strip and immerse part of the test strip in the sample, then take out the test strip for reading the results. Technicians may be exposed to samples to endanger their health or contaminate the samples. In order to avoid such risk, it is necessary to add the sealed cover on the sample collection container. At present there are a variety of closed devices, for example, the devices disclosed in U.S. Pat. Nos. 4,976,923, 5,429,804, and 6,726,879. The test strips are secured to the lid of the detection apparatus. When used, the container is turned over or tilted to allow the samples to immerse the test strips for testing. The U.S. Patent Application Publication No. US2003/0027359A1 published on Feb. 6, 2003 disclosed a urine cup for detection. For the urine cup for detection, the push rod pushes the piston to move when the cup opening is covered by the lid and make the fluid samples to flow out of the cup chamber and wet the detection element. The Chinese published patent application 200510113977.5 discloses a urine cup for detection. This kind of urine cup can start the liquid to flow from the collection chamber to the detection chamber after the lid is covered to the opening of the cup, to initiate the start of testing. The urine cup starts the testing after the lid is covered to the opening of the cup.
Many other sample collection and testing devices are inefficient in extracting samples from the collection device, with many problems, such as environmental contamination caused by leakage of samples, or the test results are affected by less or more samples collected, or the detection is complicated with a number of operating steps. Many of these devices are very complex in the design and manufacturing, requiring expensive materials. Therefore, it is necessary to collect and test samples with better method and apparatus.
Recently, this detection apparatus has been increasingly used by ordinary families or non-professional organizations. Since these test evaluations are designed for non-professionals, these detection apparatuses should be simple to operate and ensure the accuracy of the test results. Therefore, it is urgent to have a kind of detection apparatus with simple operation and accurate and reliable test results. The present invention is to provide a detection apparatus that meets such needs.
SUMMARYThe present invention provides a simple detection apparatus. Specifically, it provides a urinal cup for testing that is easy to operate. When the lid is covered to the opening of the cup, the prompting device on the urine cup will prompt if the lid is covered to the specified location. On the one hand, when the lid is covered to the opening of the cup, the degree of tightness of the lid covered to the opening of cup may vary when operated by different operators especially non-professionals, which may cause unable to seal the opening of the cup and possibility of leakage. For the present invention, a prompting device is arranged on the detection apparatus, when the lid is covered to the specified location of the collection chamber (the opening of the collection chamber can be adequately sealed by the cover in the location), the prompting device prompts that the opening of the collection chamber is sealed by the lid and operators need not cover the cover again. By this way, the opening of each apparatus can be fully sealed without fear of leakage.
On the other hand, in some apparatus, once the lid is closed to the opening of the collection chamber, the liquid sample in the collection chamber will contact with the testing element for testing; at this time, it is required to start to calculate the time, wait for a period of time and read the test results in the detection region of the testing element. When operated by different operators, since the starting time is not consistent, without a unified standard, the test results may be different for different operators. The present invention provides a detection apparatus, and when the lid is covered to the specified location of the collection chamber, the prompting device gives prompt information, such as a sound, to tell the operators the time to wait for the test results from testing element.
On one hand, the present invention provides an apparatus for detecting the presence or absence of an analyte in liquid sample, including: a collection chamber, including an opening for collecting a liquid sample; a testing element for testing the analyte in liquid sample; and a cover for covering the opening of the collection chamber; wherein the apparatus further includes a prompting device for prompting if the cover is covered to a specified location.
In some preferred ways, when the cover is covered to a specified location, the prompting device prompts that the opening of the collection chamber has been sealed, or when the cover is covered to the specified location, the prompting device prompts to the time to wait for the test results from testing element.
In some preferred ways, the prompting device gives prompts by making a sound. In some specific ways, the prompting device includes one or more elements, for example, the first and the second elements, which can give sounds by elastic deformation. In some preferred ways, specifically, the prompting device includes a first and a second elements, when the first element is in contact with the second element and one of them is deformed such as the first element, the two elements are in contact with each other to generate elastic deformations of both or one element, to rebound and collide each other to make a sound to give prompt, for example, when the first element is deformed, to collide with the first element, or one element has a self-vibration after a deformation occurs, to make a sound. In some preferred ways, the two elements contact each with to produce friction and make sound, to give prompt, for example, when the first element and the second element contact each with to produce friction, and one element for example the first element produces vibration to make a sound.
“Collision” refers to contact in a short period of time suddenly after separated by a certain distance, to make a sound. The sound produced by friction is that two elements have been in contact with each other to do relative movement, to drive two elements to produce surface contact friction and make a sound with the movement, which does not need to separate, or the sound is made by one or both of the mechanism of “mutual collision” and “mutual friction”. Generally for the mechanism of sound generation, whether mutual collision, friction or beating, one or two elements can vibrate to make sounds, preferably, one of the elements vibrates to make sound, or two elements vibrate, and the superposition effect of the sound waves makes the sound louder or more pleasing.
In a specific way, the prompting device includes an elastic element, for example, a first element; and a non-elastic element, for example, a second element, when the elastic element passes through the non-elastic element, with the blocking or hindering of the non-elastic element, the elastic element produces elastic deformation; when the blocking force disappears, the elastic element has the power to develop to the original state, to collide with the blocked non-elastic element and make a sound. The terms “elastic element” and “non-elastic element” as used herein are relative concept. In terms of setting, generally the elastic modulus of the elastic element is less than the elastic modulus of the non-elastic element. For example, the plastic is used as an elastic element, and metal such as iron, steel or lead is used as a non-elastic element, in this way, with the mutual force of plastic and non-elastic element, the elastic modulus of elastic element is less than that of the non-elastic element, when they have the same mutual force, the elastic element is more likely to change in shape, and when the force disappears in an instant, the elastic element needs to be restored to the original state, thereby beating or vibrating to make a sound. The force exerted on the element where the elastic deformation occurs is generally less than the inherent elasticity limit of the element, so that they can recover themselves when the external force disappears. Alternatively, both elastic element and non-elastic element are plastic materials.
In some preferred ways, there is one elastic element, such as a first element, and two non-elastic elements, such as the second and third elements, when the elastic element passes through non-elastic elements, one non-elastic element, e.g. the second element, hinders or blocks the elastic element, which causes the deformation of the elastic element, then the elastic element collides with another non-elastic element, e.g. the second element to make a sound. Or there is one elastic element and one non-elastic element, when the elastic element through the non-elastic element, the elastic element is subject to change in shape due to the resistance, and once the resistance disappears, the elastic element may rebound to collide with the resistance element to make a sound.
In some other preferred ways, the two elements do not necessarily need to be an elastic element, while the other is a non-elastic element. The material of the two elements may be elastic elements, or none is elastic element, but due to different physical size, under the same interaction force, one element has elastic deformation and another element does not have deformation. The interaction force is different due to different force fulcrum of the two elements, for example, for the plastics with the same material, their thickness is the same but their length is different, the shorter one is used as a resistance element, and the longer one is used as a deformed element, when the long element moves relative to the short element, once they are in contact, due to the same interaction force, the longer element is deformed but the shorter one is almost not deformed, thus, when the longer element passes through the shorter one, due to deformation, it needs to restore to its original state, to collide with the shorter one to make a sound. At this time, the two elements may be of the same material, but due to different size and force, one is greatly deformed and the other is almost not deformed, or the longer element may vibrate itself and make sound after deformation, or when the long element is in contact with the short element, they produce friction each other to make the longer element to vibrate and make a sound, the long element is easy to produce deformation or vibration than the short element. When the two elements have the same length and material, and same contact force, but since the surface is rough with great friction, it is possible to make one element to make a sound.
More preferably, an elastic element or a long element, for example, a first element, may be located on a cover, for example, an outer edge of a cover; a non-elastic element or a short element, for example, a second element and/or third element, may be located on the outer wall surface of the cup. In a more specific embodiment, the long element and/or elastic element form an angle with the short element and/or non-elastic element, for example, 90 degrees, 60 degrees, 45 degrees, 30 degrees, or 25 degrees. With such setting of angle, during the mutual movement of the long element and/or elastic element with the short element and/or non-elastic element, they will contact each other in a position, to make a sound. In a preferred embodiment, the long element and/or elastic element is arranged perpendicularly to the short element and/or non-elastic element. Of course, alternatively, the elastic element or long component can be located on the cup body, e.g. the outer edge of the cup body; and the non-elastic elements or short element can be located on the cover.
In some preferred ways, the long element and/or elastic element are arranged on the cover and parallel to the central axis of the cover, the short element and/or non-elastic element are arranged on the cup body, perpendicular to the central body of the cup body. In some preferred embodiments, the vertical length of the long element is greater than the length of the short element. In some preferred embodiments, one end of the long element is located in a chamber of the cover and extends outwardly from the chamber, slightly above the opening of the chamber. In some preferred embodiments, the region where the long element is elastically deformed is longer or greater than the region where the long element is in contact with the short element. In this way, the region with actual deformation of the long element is easy to deform compared to the short element, when they produce friction, the region with actual vibration for the long element is greater than that of the short element, to facilitate to make a sound.
In some preferred ways, the camber on the cover is located on the outer peripheral edge of the cover, and as the cover rotates, the long element also moves with the cover. In some preferred embodiments, the short element is located on the outer wall of the cup body. More specifically, it is located on the plane of the ring edge of the cup body extending outwardly, for example, the skirt. In some preferred ways, the ring edge has a certain angle from the centerline of the cup body, for example, 10 degrees, 20 degrees, 30 degrees, 45 degrees, 60 degrees, 70 degrees, or 90 degrees. The short element or non-elastic element is located on the plane of the ring edge. Here, the short element or the non-elastic element may be provided separately on the cup body of the injection modeling, may be protruded upwardly from the plane of the ring edge to form a protruding rib, which may be 0.1 mm-1 mm or 2-3 mm high, so long as the long element can contact with the rib transversely when moving to a certain position.
In other specific embodiments, the non-elastic element is made of ABS material; elastic element is made of PP material. Alternatively, when the elastic element passes through the non-elastic element and beat the non-elastic element, the elastic element is prevented from being moved by the non-elastic element so that it can not move clockwise relative to the cup body. In another alternative embodiment, when the elastic element passes through the non-elastic element, the elastic element can move clockwise relative to the cover. Alternatively, the way that the cover covers to the opening of the collection chamber is to seal the opening of the collection chamber by the cover through rotation, the opening includes the external thread matching with the cover, and the cover includes the internal thread that matches the opening.
In another aspect, the present invention provides a method of detecting analyte in a sample, including providing a detection apparatus, including: a collection chamber including an opening for collecting a liquid sample, a testing element for testing the analyte in liquid sample, and a cover for covering the opening of the collection chamber; The cover is covered to the opening of the collection chamber and one prompting device on detection apparatus prompts whether the cover is closed to the specified location. In one way, the prompting device prompts by making a sound. In another way, once you hear the prompting device to give a prompt, stop continuing to cover the cover to the collection chamber's opening. In a specific way, the cover closes the opening of the collection chamber in a rotation way, and when you hear the prompting device, it is prompted to stop the cover. In addition, in a way, once you hear the prompting device to give a prompt, start calculating the time to wait for the test results from testing element. In another way, once you hear the prompting device to give a prompt, start calculating the time to wait for the test results from testing element, and stop rotating the cover.
The present invention provides a method for detecting analyte in a sample including: providing a detection apparatus including a collection chamber containing an opening; a testing element; and a cover for sealing the opening of the collection chamber through rotation relative to collection chamber, wherein the apparatus furthers includes a prompting device that prompts whether the cover is rotated to the specified location; rotating the cover until the prompting device gives prompt.
In some preferred ways, when the prompting device gives prompt, the rotation is stopped. Alternatively, when the prompting device gives prompt, it begins to calculate the time to wait for the test results from testing element. In a specific way, the prompting device gives prompt by making a sound.
In another aspect, the present invention provides a detection apparatus, including: a collection chamber including an opening for preparing a liquid sample; a testing element for testing analyte in a liquid sample; and a cover to cover the opening of the collection chamber; wherein the cover includes a first element, and the cover body includes a second element. When the first element is in contact with the second element, they produce friction to make a sound. In some preferred embodiments, the sound is made through friction between the first element and the second element during the relative movement. In some preferred embodiments, the movement of the cover relative to the cup body drives the movement of the first element relative to the second element. In some preferred embodiments, the movement of the cover relative to the cup body is a relative rotational motion. In some preferred embodiments, the friction between the first element and the second element makes the first element easy to deform or vibrate, to make a sound.
In all of the above specific embodiments, the structures making a sound, for example an elastic element and a non-elastic element, or a long element and a short element, constitute a sound structure or device; one or more structures are distributed on the detection apparatus. Preferably, the two or more sound structures give sounds simultaneously and the two sounds resonate. With the resonance, the sound is more crisp and loud. Alternatively, the two sound sources simultaneously emit a frequency or the same sound wave, and the two sounds are superimposed on each other to make the audible sound louder. In some preferred embodiments, the structures making a sound are distributed symmetrically. In some preferred embodiments, there are three structures making a sound, which are distributed evenly at an angle of 120 degrees of the circumference. In some preferred embodiments, three structures or devices making sounds are distributed around a concentric circle.
The structures involved in this invention or the used technical terms are further described below. These descriptions are only to explain how to achieve the ways in this invention through examples, and will not restrict this invention. The scope of this invention is defined and expressed by claims.
Detection
Detection means to assay or test the presence or absence of a substance or material, including but not limited to chemical substances, organic compounds, inorganic compounds, metabolic products, medicines or drug metabolites, organic tissues or metabolites of organic tissues, nucleic acids, proteins or polymers. Additionally, detection means to test the quantity of, or the presence or absence of a substance or material. Furthermore, assay also means immunodetection, chemical detection, enzyme detection, nucleic acid detection and etc.
Downstream and Upstream
Downstream and upstream are divided according to the flow direction of liquid, and generally, liquid flows from upstream to downstream regions. The downstream region receives liquid from the upstream region, and also, liquid can flow to the downstream region along the upstream region. Here we often divide the regions according to the flow direction of liquid. For example, on some materials that use capillary force to promote liquid to flow, liquid can flow against the gravity direction, at this time, the upstream and downstream regions are still divided according to the flow direction of liquid.
Gas Flow or Liquid Flow
Gas flow or liquid flow means that liquid or gas can flow from one place to another place. In the flow process, some physical structures may play a role of guidance. Here, liquid or gas can flow due to self action (gravity or pressure), and can also be driven to flow.
Testing Element
Various testing elements can be combined and applied to this invention. The testing element includes a test strip, which can be analyzed in various forms such as immunoassay or chemical test to detect such analyte in samples as drugs or relevant metabolites indicating physical conditions. In some forms, the test strip is a water absorbent material having liquid sample adding (applying) area, reagent area and testing result area. Samples are added to the adding area, and flow to the reagent area under the capillary action. In the reagent area, samples dissolve the reagent and mix with it to detect analyte (if there is analyte in samples). Certainly, the reagent area and the sample adding area can also be the same one area. Some reagents treating liquid samples are disposed in advance in the adding area. And samples with reagents continue to flow to the testing result area. Other reagents are fixed in the testing result area, and these reagents react and combine with analyte (if there is analyte in samples) or the first type of reagent in the reagent area. In the noncompetitive detection form, if there is analyte in samples, signals will be generated; and if not, signals will not be generated. In the competitive detection form, if there is no analyte in samples, signals will be generated; and if not, signals will not be generated. The invention applies to the testing element of various analytic forms.
When the testing element is a test strip, it can be made from water absorbent or non-water absorbent materials. A test strip can use various materials to transmit liquid, and one material can be superposed on another material. For example, a filter paper can be superposed on the nitrocellulose. Or in the test strip, a region that at least contains one material is located behind the other region that at least contains a different material. In such case, the liquid circulates among regions, and they can be superposed on one another or choose not to superpose. Materials on the test strip can be fixed on (for example) the holder or hard surface of the plastic gasket, to enhance the test strip's sustainable power.
In some embodiments where some detected objects are detected through a signal generation system (for example, at least one enzyme reacts specifically with the detected object), at least one substance generating signals can be absorbed on the analyte detecting area of the test strip, just like being absorbed specifically on the materials of the test strip as described above. In addition, substances generating signals in the sample adding area, reagent area and analyte detecting area of the test strip or all over the whole test strip can be pretreated in advance on one or more materials of the test strip, which can be achieved by adding the solution of substances generating signals to the surface of the application area or soaking one or more materials of the test strip in the signal solution, after which dry the test strip. Moreover, the above method can be used to pretreat substances generating signals in the sample adding area, reagent area and analyte detecting area of the test strip or all over the whole test strip in advance on one or more materials of the test strip. Furthermore, the signal substance existing in the sample adding area, reagent area and detecting area of the test strip can be added to one or more surfaces of the test strip materials as the labeling reagent.
Areas of the test strip can be arranged as follows: a complete and necessary test strip can include a sample applying area and a testing area. Generally, liquid first contacts the sample adding area, and then flows to the testing area under the capillary action. Certainly, the test strip can also include the following areas according to the needs: a sample adding area or applying area, or at least a reagent area, and a testing area which includes a testing result area, or at least a control area, or at least an adulteration detecting area and a liquid absorption area. If the detecting area includes a control area, the preferred control area is located behind the analyte detecting area of the testing result area. All these areas or their combinations can be on a single test strip containing a material. Additionally, these areas are made from different materials, and are connected together according to the transmission direction of liquid. For example, liquid can be transmitted directly or indirectly among different areas. In this embodiment, different areas can be connected end to end or superposed mutually along the direction of liquid transmission, or connected through other materials such as connecting medium materials (water absorbent materials such as filter paper, glass fiber or nitrocellulose are preferred). By use of the connecting materials, the liquid can flow on materials that connect each area end to end, materials that connect each area end to end but the liquid does not flow, or materials that each area is overlapped mutually (including but not limited to overlapping from end to end) but the liquid does not flow.
If the test strip contains an adulteration detecting control area, the area can be arranged before or after the result detecting area. When the result detecting area contains a control area, the adulteration control area is preferred to be arranged before the control area. In one embodiment of this invention, the test strip is used for analytical judgment and/or control of adulteration. The adulteration control area can be arranged before or after the control area, and preferably, before the control area.
The nitrocellulose membrane test strip is commonly used, that is, the detecting area includes a nitrocellulose membrane on which specific combination molecule is fixed to display the detecting result; and other test strips such as cellulose acetate membrane or nylon membrane test strips can also be used. The test strips and similar apparatuses with test strips disclosed in the following patents can be applied to the testing elements or detection apparatuses in this invention for analyte detection, such as the detection of the analyte in the sample: U.S. Pat. Nos. 4,857,453; 5,073,484; 5,119,831; 5,185,127; 5,275,785; 5,416,000; 5,504,013; 5,602,040; 5,622,871; 5,654,162; 5,656,503; 5,686,315; 5,766,961; 5,770,460; 5,916,815; 5,976,895; 6,248,598; 6,140,136; 6,187,269; 6,187,598; 6,228,660; 6,235,241; 6,306,642; 6,352,862; 6,372,515; 6,379,620 and 6,403,383.
In the specific embodiment of this invention, any forms of testing elements or test strips can be located in one or more card slots of base layer 400 or 500 or slot 501 or slot 403, or in the channel that covers the elements (omission) and the card slots on the base layer. Detailed descriptions on how to arrange the test strip in the detection apparatus in this invention will be given below.
Samples
The detection apparatus provided in the invention can be used to detect samples including biological liquid (such as case liquid or clinical samples). The liquid sample or fluid sample can come from solid or semi-solid samples, including excreta, biological tissues and food samples, and these solid or semi-solid samples can be converted to liquid samples by using any suitable methods such as mixing, crushing, macerating, incubating, dissolving or digesting the solid samples in a suitable solution (such as water, phosphate solution or other buffer solutions) with the enzymolysis. “Biological samples” include samples from animals, plants and food, such as urine, saliva, blood and its components, spinal fluids, vaginal secretion, sperms, excrement, sweat, secreta, tissues, organs, tumors, cultures of tissues and organs, cell cultures and media from human or animals. The preferred biological sample is urine; food samples include food processed substances, final products, meat, cheese, liquor, milk and drinking water; and plant samples include samples from any plants, plant tissues, plant cell cultures and media. “Environmental samples” come from the environment (such as liquid samples coming from lake or other water bodies, sewage samples, soil samples, underground water, sea water and effluent samples), and can also include waste water or other sewage water.
Any analyte can be detected by using this invention and a suitable testing element. Preferably, this invention is used to detect the drug micromolecules in saliva and urine.
Analyte
Examples that can use the analyte related to this invention include some hapten substances, including drugs (such as drug abuse). “Drug abuse” (DOA) means to use drugs (often to paralyze the nerves) for non-medical purposes, which will lead to physical and mental damages, and people who use drugs will be dependent on, addicted to drugs and/or die. Examples of drug abuse include abuse of cocaine, amphetamine AMP (e.g. Black Beauty, white amphetamine tablets, dextroamphetamine, dextroamphetamine tablets, Beans); methylamphetamine MET (crank, meth, crystal, speed); barbiturate BAR (such as Valium, Roche Pharmaceuticals, Nutley, N.J.); sedatives (i.e. sleeping adjuvants); lysergic acid diethylamide (LSD); inhibitors (downers, goofballs, barbs, blue devils, yellow jackets, methaqualone); tricyclic antidepressants (TCA, i.e. imipramine, amitriptyline and doxepin); methylene dioxymetham-phetamine MDMA; phencyclidine (PCP); tetrahydrocannabinol (THC, pot, dope, hash, weed and etc.); opiates (i.e. morphine MOP or opium, cocaine COC, heroin, OXY); antianxiety drugs and sedative hypnotics, the antianxiety drugs are drugs mainly used to relieve anxiety, tension, fear and stabilize emotions, having the function of hypnosis and sedation, including BZO (benzodiazepines), atypical BZ, fused dinitrogen NB23C, benzodiazepines, ligand of BZ receptors, open-loop BZ, diphenylmethane derivatives, piperazine carboxylate, piperidine carboxylate, quinazolinones, thiazines and thiazole derivatives, other heterocyclic, imidazole sedatives/painkillers (such as OXY, MTD), propanediol derivatives-carbamates, aliphatic compounds, anthracene derivatives and etc. The detection apparatus provided in this invention can also be used to detect medicines that are easy to overdose for the medical purpose, such as tricyclic antidepressants (imipramine or analogues) and acetaminophen. These medicines will be resolved into different micromolecular substances after being absorbed by human body, and these micromolecular substances will exist in blood, urine, saliva, sweat and other body fluids or in some of the body fluids.
For example, the analyte detected by this invention includes but not limited to creatinine, bilirubin, nitrite, (non-specific) proteins, hormones (such as human chorionic gonadotropin, progesterone hormone, follicle-stimulating hormone), blood, leucocytes, sugar, heavy metals or toxins, bacterial substances (such as proteins or sugar substances against specific bacteria, such as Escherichia coli 0157:H7, staphylococcus, salmonella, fusobacterium, campylobacter, L. monocytogenes, vibrio or Bacillus cereus) and substances relevant with the physiological features in the urine sample, such as pH and specific gravity. For any other clinical urine chemical analysis, the detection can be made by combining the lateral cross flow detection form and the apparatus provided in this invention.
Detection Apparatus
The detection apparatus provided in the present invention, 600 as shown in
In a specific embodiment, the detection apparatus includes a collection chamber used to collect and store liquid samples, referring to the collection chamber shown in
The prompting device provided in this invention can also be applied to other detection apparatuses, particularly, to those apparatuses containing cover and using cover to seal the opening of the collection chamber. These similar apparatuses are described specifically in US patents that have been published such as U.S. Pat. Nos. 7,270,959; 7,300,633; 7,560,272; 7,438,852; 4,976,923; 5,429,804 and 6,726,879. The prompting device disclosed in this invention can be combined to the specific ways of each detection apparatus disclosed in the above patents as one of the specific ways of this invention.
Prompting Device
In a specific way, the prompting device can be arranged on the detection apparatus. The prompting device gives prompts by making a “Pa”, “Peng”, “Dong”, “Dingling”, “Pipa” sound or any other suitable sounds. Preferably, such sound can be heard by people.
In some other ways, the opening of the collection chamber is sealed by the cover through relative rotation, a part of the prompting device is located on the cover, and the other part is located on the wall of collection chamber. When the cover is rotated to seal the opening, the part of promoting device on the cover and the other part on the collection chamber generate elastic deformation under the interaction force, and after the force disappears, the parts having elastic deformation collide each other to make a sound to give prompts.
The operating principle of the prompting device provided in this invention is illustrated in combination with
The first way of making sounds. The prompting device includes a first element and a second element, which can make a sound by friction between the first element and the second element. Conclusively, the first element has regions that are easier to deform than the second element. For example, since the length of easily deformed regions of the first element 800 is greater than that of the second element, after the two elements are in contact with each other and receive the same force, one element deforms. Or, since the width of easily deformed regions of the first element 800 is greater than that of the second element, after the two elements are in contact with each other and receive the same force, one element deforms. Or, the area of easily deformed regions of the first element 800 is greater than that of the second element, after the two elements are in contact with each other and receive the same force, one element deforms.
For example, the prompting device includes a first element 800 and a second element 900, and generally the first element is located on the cover 200, and the second element 900 is located on the cup body 100. Certainly, the first element can also be located on the cup body 100, and the second element 900 can be located on the cover 200. When the first element and the second element move relative to each other to a certain position, the two elements are in contact with each other (
The second way of making sounds. Of course, in some other ways, as the first element and the second element continue to move, the first element slides through the second element to leave away from the second element. Since the first element is deformed (for example, bent or twisted), it is required to restore to its normal initial state and produce vibration to making a sound (
The third way of making sounds. Of course, in other specific ways, to make the sound clearer, there are two second elements (second element 900, third element 700), when the first end 802 of the first element passes through the second element 900 and leaves the first element, since the second end 801 of the first element 800 (fixed end, generally connected with the cover) is in the front position and the first end 802 is in the back position due to resistance, when leaving from the first element, both ends of the first element have a trend to return to the same position, the first end 802 moves forward to the position of the second end represented by 801, so that the first end 802 moves forward to collide with the third element to produce a sound. The position of the third element 700, or the distance between the second element 900 and the third element should be less than the distance between the fixed end 801 of the second element and the first end of the first element obstructed. The fixed end of the first element is in the same location as that of the blocked end 801. Since the first end 802 of the first element is blocked by the second element so that the fixed end 801 of the first element and the blocked end 801 of the first element produce a position shift. The position shift is associated with the resistance exerted on the first end, the distance between the fixed end 802 and the blocking end (first end 802), and the length or height of the second element. Generally the greater the distance between the fixed end 802 and the blocking end (first end 802), the greater the position shift, or the greater the resistance, the greater the position shift, or the higher the second element, the greater the resistance and the greater the position shift (
The above three ways can make a sound, but one, or two or three ways can be chosen to make a sound. Of course, as shown from
In some preferred ways, referring to figures, how the sound is emitted from detection apparatus is illustrated, for example,
The first element on the cover is illustrated with reference to
For the cup body 100, similar second element can be provided. The second element can be, for example, a second plastic sheet, which is arranged on the outer surface of the cup body (
In order to allow the cover 200 to rotate to seal the cup body, a thread is arranged on the face of the outer edge 116 of the opening 115 of the cup body, and the cover rotates with the cup body through the thread, to move downwards along the vertical axis of the cover and cup body, so that the side 210 of the cover edge 221 of the cover 200 is gradually close to the skirt 103 of the cup body 100. The distance between the threads in the cover and the threads outside the cup body allows the first plastic sheet 208 on the cover to be located just before the second plastic sheet 106 when the cover is sealed in the opening of the cup body or just to seal the opening. (
In addition, based on the above discussion, when the fixed end 2082 of the first plastic sheet moves forward with the cover, the blocked end 2081 is blocked by the second plastic sheet, by this way, the end 2082 fixed on the cover and the plastic sheet before the first end 2082 will be distorted, bent or deformed. Once the resistance disappears (without the blockage of the second plastic sheet 106), the bent end 2082 will move forward quickly, to produce vibration and thus make a sound during the movement.
As a preferred embodiment, a third plastic sheet 107 is provided on the cup body, which is arranged in parallel with the second plastic sheet, with a distance between them. With the setting of the distance, the first end 2081 of the bent first plastic sheet will move forward quickly after leaving the second plastic sheet 106, to hit the third plastic sheet 107. This hitting will make a sound, and the first plastic sheet will produce vibration and make a sound.
For example, as shown in
In some other ways, the second plastic sheet 106 or the third plastic sheet 107 is protruding upwards from the surface of the skirt 103 of the cup body, to touch the first plastic sheet. In order to prevent the second plastic sheet 208 from exposed outside, a chamber 207 is provided on the cover to receive the first plastic sheet 208, to allow the fix end 2082 of the first plastic sheet 208 to be secured in the chamber and another end 2082 is exposed outside of the chamber. In order to contact the second plastic sheet 106 on the cup body, the other end 2082 of the first plastic sheet is exposed to a certain height (
Of course, in order to allow the cover to rotate smoothly, before one end 2081 of the first plastic sheet 208 is in contact with the second or third protruding plastic on the surface of skirt 103, the end 2081 of the first plastic sheet 208 is not in contact with the surface of the skirt 103, thereby reducing the friction between one end 2081 of the first plastic sheet 208 and the surface of the skirt 103 and reducing the resistance. In this way, only when rotating to the fixed position or the pre-set position, the end 2081 of the first plastic sheet 208 can be in contact with the second plastic sheet 106, thereby making a sound as described above.
As the principle of the workflow illustrated in
In some preferred embodiments, the second plastic sheet or second plastic element 106 or the third plastic sheet or third plastic element 107 is in contact with the first plastic element or the first plastic sheet 208 at an angle of 90 degrees or any other angle, such as 80 degrees, 70 degrees, 45 degrees, as long as they can contact each other. Of course, the most preferred way is within the angle of 80-90 degrees. Of course, it is preferred that the material of the second plastic sheet or the second plastic element 106 or the third plastic sheet or third plastic element 107 is same as that of the cup body, or may be different, and when the material is the same, it can be easily made by one-time injection molding.
In these embodiments, since the second plastic sheet or the second plastic part 106 or the third plastic sheet or the third plastic element 107 is protruding, with a certain height, while one end 2082 of the first plastic element or the plastic sheet 208 is fixed on the cover, while the other end 2081 is suspended, and the length between the other end 2081 and the fixed end 2082 will decide the degree of bending and deformation of the first plastic element, and if the distance between them is longer, the deformation may easily occur, and a small force may induce deformation; on the country, the shorter, the more difficult for deformation and deformation needs a large force. Of course, this distance, i.e. the length or distance between the other end 2081 and the fixed end 2082, is greater than the height of the second plastic sheet or second plastic element 106 or the third plastic sheet or third plastic element 107 protruding on the skirt. By this way, it is easy to make a sound when the material of the first element or second plastic element is the same as that of the second or third element or the second or third plastic element.
Alternatively, in some alternative embodiments, when the material of the first element or second plastic element is not the same as that of the second or third element or the second or third plastic element, the first element may be of an elastomeric material such as a thin plastic sheet, a thin metal sheet, and the second element is of a rigid material, such as a hard plastic, or a hard metal strip, so that the elastic element is in contact with the rigid second element. As described aforesaid, the first element is prone to deformation and make a sound.
In some preferred embodiments, three identical parts of the sound structure (
In still some preferred embodiments, there are three (
Collection Chamber and Detection Chamber
Referring to the structure of a cup body shown in
In some preferred ways, the triangle region 113 extruding upwards on the bottom of the cup body and the three support surfaces form a collecting tank 118 for easily collecting the liquid sample, and making it easier for the test strip on the base layer to absorb the liquid sample. In this way, even if there is little liquid sample, the detection can also be completed (
In some other ways, the invention provides some other embodiments, referring to
As shown in
Base Layer with Slots
As the collection chamber disclosed above, the test strip can be arranged in the chamber individually, and it can also be put in the base layer with card slots, thus detecting various analytes in a liquid sample. Referring to the base layer 400 shown in
The back of the base layer is not flat and smooth, which consists of several surfaces with different height. On the upper part of the base layer there is a slope 401, making the cross section of the base layer thinner, and letting the clamping lock 112 easily lock the upper part of the base layer. In addition, there is depressed guide groove 409 at the back of the two supporting legs 404 and 404, through which it is easy to lead in the guide rail formed by locking anchors 110 and 111 on the cup body. Actually, the two guide grooves 409 have a particular structure, this is because in the actual production of the cup body, the distance between the two locking anchors 110 and 111 and the support surface has tolerance, that is, sometimes the distance is longer and sometimes is shorter. When the distance is longer, it is easy to insert into the guide groove formed by the two supporting legs on the base layer, but it is not easy to fix the base layer on the support surface; and when the distance is shorter, it is very difficult to insert. Thus, we can change the depth of the guide groove on the base layer to let the base layer closely cooperate with the guide rail formed by the two locking anchors 110 and 111. When the distance is longer, make the guide groove side shallower; and when it is shorter, make the guide groove side deeper.
In some other ways, the structure of the base layer can be similar to that of the base layer 400 (
In some other ways, the structure of the base layer can be that of the base layer shown in
Detection Method
The present invention provides a method for detecting analyte in a sample, including providing a detection apparatus, including: a collection chamber including an opening for collecting a liquid sample, a testing element for testing the analyte in liquid sample; and a cover for covering the opening of the collection chamber; covering the lid to the opening of the collection chamber, so that one prompting device on the detection apparatus can prompt if the cover is covered to the specified location. In one way, the prompting device gives prompts by making a sound. In another way, once you hear the prompting device to give a prompt, stop covering the cover to the opening of the collection chamber. In a specific way, the cover closes the opening of the collection chamber by rotating; and when hearing prompt given by the prompting device, you can stop rotating the cover. In addition, in a way, once you hear a prompt given by the prompting device, start calculating the time to wait for the test results from testing element. In another way, once you hear a prompt given by the prompting device, start calculating the time to wait for the test results from testing element, and stop rotating the cover.
Example 1Referring to
Fifty negative samples are mixed with mixtures of drug abuse, including amphetamines, cocaine, methamphetamine, opiates, THC and phenylcyclohexane, in addition, 50 negative samples are provided.
When testing, these urine samples are poured into the cup, and the cover is covered to the cup body; when a “crackling” sound is heard, stop rotating and wait for the end of the test.
Then a real leak test is performed for the covered detection apparatus, and all detection apparatuses are found to keep sealed without leakage of samples.
The invention shown and described herein may be implemented in the absence of any elements, limitations specifically disclosed herein. The terms and expressions used herein are for illustration rather than limitation, which do not exclude any equivalents of the features and portions described herein in the use of these terms and expressions, in addition, it should be understood that various modifications are feasible within the scope of the present invention. It is therefore to be understood that, although the invention has been particularly disclosed by various embodiments and alternative features, modifications and variations of the concepts described herein may be employed by those of skilled in the art, and such modifications and variations will fall into the scope of protection of the present invention as defined by the appended claims.
The contents of the articles, patents, patent applications, and all other documents and electronic information available or documented herein are incorporated herein by reference in their entirety, as if each individual publication is specifically and individually indicated for reference. The applicant reserves the right to incorporate any and all materials and information from any such article, patent, patent application or other document into this application.
Claims
1. An apparatus for detecting the presence or absence of an analyte in a liquid sample, comprising:
- a collection chamber, comprising an opening for collecting a liquid sample;
- a cover for covering the opening of the collection chamber; and
- a cup body comprising the collection chamber;
- wherein the apparatus further comprises a prompting device for prompting if the cover is covered to a specified location on the collection chamber, and the prompting device comprises a first element, a second element, and a third element, wherein the first element is elastic, and the second element and the third element are non-elastic.
2. The apparatus according to claim 1, wherein the first element, with a first end and a second end, is located on the cover, the second element and the third element are located on the cup body.
3. The apparatus according to claim 2, wherein when the first end of the first element passes through the second element that blocks the first element, the second element causes deformation and vibrations of the first element, which produce a sound as to prompt that the cover is covering the specified location.
4. The apparatus according to claim 3, wherein the cover comprises a chamber, wherein the chamber comprises an opening and the chamber is located on a outer surface of a edge of the cover; and wherein the first end of the first element is fixed in the chamber, the second end of the first element is suspended.
5. The apparatus according to claim 2, wherein the second element and the third element are located on an outer edge of the cup body.
6. The apparatus according to claim 1, a friction is produced when the first end of the first element passes through the second element, and the friction causes the first element to generate the vibrations.
7. The apparatus according to claim 1, wherein the first element produces a deformation when the first element is in contact with the second element and the deformed first element needs to restore to no-deformation as to produce the vibrations.
8. The apparatus according to claim 1, wherein the second element and the third element are located on a skirt of the cup body and perpendicular to a central axis of the cup body.
9. The apparatus according to claim 8, wherein the second element and the third element are formed by a protrusion of the skirt.
10. The apparatus according to claim 2, wherein the second end of the first element is blocked by the second element to produce deformation when the cover is covered to an outer edge of the opening of the cup body, when a blocking force of the second element exerting on the second end of the first element disappears, the deformed first element collides with the third element to produce the vibrations.
11. The apparatus according to claim 1, wherein a length of the first element is greater than a height of the second element or the third element.
12. The apparatus according to claim 1, wherein the first element is of the same material as the second element or the third element, and wherein the length of first element deformation is greater than the height of the second and the third element.
13. The apparatus according to claim 8, wherein the cup body comprises a threaded structure and the skirt is located below the threaded structure.
14. The apparatus according to claim 1, wherein the cover comprises three first elements, and the cup body comprises three second elements and three third elements corresponding to the three first elements.
15. The apparatus according to claim 1, wherein the collection chamber comprises a testing element and the testing element is located in a groove of a base layer.
16. The apparatus according to claim 15, wherein a cross section of the collection chamber is of a triangular shape and the collection chamber comprises three faces relying on the base layer.
17. The apparatus according to claim 1, wherein the liquid sample is urine sample.
Type: Application
Filed: Apr 20, 2022
Publication Date: Aug 4, 2022
Inventors: Jianqiu Fang (HOUSTON, TX), Siyu Lei (Zhejiang)
Application Number: 17/725,358