Patent Application
20190224685
The invention relates to a sample holder for specimen containers, such as test tubes, that allows for easy analysis of multiple samples while also decreasing the risk of spilling said samples.
Previous sample holders have certain disadvantages. Currently available sample holders are prone to spilling. For example, spilling often occurs when specimen samples are collected and placed in the holder, such as when specimen samples are taken from fresh or salt water tanks used to hold and study fish and other marine life. Spilling can also occur after specimen samples are placed in a sample holder, for example when the chemical and physical properties of specimen samples are tested using reagents or assays. Such spillage during testing can occur when reagents or assays are added to the samples, when samples are removed from or returned to the sample holder to facilitate testing, or otherwise during the course of testing. Moving traditional sample holders from place to place may also result in spillage of specimen samples. To the extent that any specimen samples may need to be heated or illuminated during testing, those samples and other samples contained in the holder may also be prone to spillage or loss. Severe spillage before, during, or after testing might even undermine the structural integrity of the sample holder.
There is a need for a sample holder which reduces the likelihood of a user confusing one sample with another in the course of sample testing. For example, when specimen samples are collected and placed in the holder, it may be necessary or appropriate to identify the date, time, location, or conditions of the sampling. In those cases, it can be important to avoid confusing the date, time, location, or conditions of one sample with other samples. In the course of sample testing, different reagents or assays may also be used on the same, similar, or different samples. In such cases it can be important to apply the correct reagent or assay to each sample, and it can also be important to identify and record which reagent or assay has been applied to each sample.
There is also a need for a sample holder to provide easy analysis for multiple samples at the same time. It may be important to group or collect certain samples in certain locations, so that similar samples or similar assays, reagents, or tests are collected together. Furthermore, some assays, reagents, or tests may require larger or smaller specimen samples than others, so that different sizes of multiple samples may be necessary.
It is therefore an object of the invention to provide an improved sample holder that allows for easy analysis of multiple samples while also decreasing the risk of spilling said samples. The present invention has solved the problem of having a convenient way to analyze multiple samples testing for different parameters, while reducing the likelihood of spilling or the likelihood of a user confusing one sample with another.
In one embodiment, the sample holder is designed to facilitate the water chemistry maintenance testing process of aquariums, both salt and fresh water, where water chemistry testing is needed or desired.
The analysis of saltwater environments, such as a saltwater fish tank, presents the above problems. To properly maintain the saltwater environment, a number of components must be measured and adjusted on a regular basis. These components include pH, potassium levels, sodium levels, phosphate levels, ammonia levels, nitrite levels, nitrate levels, calcium levels, and heavy metal levels.
Sample Holder presently described as the invention contained herein.
The Sample Holder provides a repository for temporary storage and analysis of samples, for example, samples held in multiple test tubes. The Sample Holder can be configured to hold multiple samples at one time. For example, the Sample Holder can hold 5 samples, 6 samples, 10 samples, 12 samples, 15 samples, 18 samples, 19 samples, 20 samples, 21 samples, 24 samples, 25 samples, 28 samples, or any other number of samples desired.
In one embodiment, the Sample Holder has means to identify each unique individual repository. These means can include, for example, digital numbers, letters, colors, codes, or the like. The Sample Holder has means to change the identifier as needed by the user.
In a preferred embodiment, the Sample Holder is used to analyze multiple components of a saltwater environment. These components can include, for example, pH, potassium levels, sodium levels, phosphate levels, ammonia levels, nitrite levels, nitrate levels, calcium levels, heavy metal levels or any other levels, reagents, or assays that may be tested or monitored.
In a preferred embodiment, the Sample Holder provides an attached shelf or workspace for reviewing the results of assays and recording the results.
In a preferred embodiment, the Sample Holder provides a digital storage and management device for recording the results of assays, including the date and time of an assay, the specific measurement made in the assay, and pertinent conditions such as temperature, salinity, the results of related assays, or other features of an assay.
In a preferred embodiment, the Sample Holder provides a digital storage and management device having a touchscreen and sufficient computing power to calculate variables relevant to an assay, including for recording the specific measurement(s) made in an assay, for recording the date and time of an assay, and for recording pertinent conditions such as temperature, salinity, the results of related assays, or other features of an assay. The touchscreen may or may not be integrated with the Sample Holder.
The Sample Holder can be made from materials well known in the art. Non-limiting examples include plastics, Plexiglas, aluminum, stainless steel, wood, or other eco-friendly or bio-degradable materials. The Sample Holder can be transparent, semi-transparent or opaque depending on the needs of the user. In one embodiment, the Sample Holder can be injection molded from a transparent, semi-transparent or opaque plastic material. The Sample Holder can be fabricated from a solid piece of material, or in the alternative, can be fabricated from multiple pieces of material that fit together or connect.
In one embodiment the base of the Sample Holder has a heated basin to enable samples to maintain a non-room temperature environment. In another embodiment, each row or column of the Sample Holder has a separate temperature control means.
In one embodiment, the Sample Holder 7 has one or more storage reservoirs. These reservoirs can hold, for example, a large quantity of sample that can be used to fill multiple sample testing tubes. These reservoirs can also hold, for example, fresh water or other solvent which can be used to clean contaminated sample testing tubes for further use. In one embodiment, the reservoirs can be part of the Sample Holder 7. In another embodiment, the Sample Holder can have means for temporarily storing removable reservoirs.
In one embodiment, the Sample Holder contains one or more internal storage compartments for storing and securing, for example, sample testing tubes. In another embodiment, the Sample Holder contains a storage slot that can hold test charts and/or test guideline sheets that allow the user to view the chart or sheet at the same time as the sample testing tubes.
In one embodiment, the Sample Holder has a vibrating base or vibrating slot that can mix the sample in the sample testing tubes and/or the reservoirs. In another embodiment, the Sample Holder has means for sonicating a sample in the sample testing tubes and/or the reservoirs.
In one embodiment, the Sample Holder has an extendable or articulating arm light for viewing samples in low light environments. The arm light can, for example, collapse into the Sample Holder or fold on top of the sample holder.
In one embodiment, the Sample Holder has means for preventing accidental falls and spills. Such means can include, for example, suction cups on the base of the Sample Holder or a textured material, such as rubber, that creates a skid proof base. The broad structure of the sample holder, in comparison to available test tub holders, also reduces the likelihood of accidental spills.
In one embodiment, the Sample Holder can have handles as part of the body of the sample holder. The handles can also be attached to the sample holder in ergonomic and/or balanced locations of the Sample Holder that enables secure transporting of the sample holder.
In one embodiment, an optional cover can be included with the Sample Holder. In another embodiment, a cover can be designed into the Sample Holder. The cover can be attached, for example, via a hinge mechanism or a slide/lock mechanism or other means known in the art.
In one embodiment, each individual sample testing tube holder opening 4 has means to keep a secure grip of the test tubes while testing that allows for easy insertion and removal. Such means can include, for example, rings made of a gripping material, such as rubber, or grommets. The rings or grommets create a grip around the sample testing tube that decreases the chances of accidental breakage from falls due to tipping, transportation of the Sample Holder, or cleaning of the sample testing tubes.
In one embodiment, the Sample Holder has electronic capabilities, including volatile and/or non-volatile memory, a processor, a storage device, a display, and input/output ports.
In one embodiment, the Sample Holder has an internal hard drive or flash memory drive capable of storing data. Such data includes, for example, test results, dates, test instructions, sample descriptions and other data gathered by use of the Sample Holder. In another embodiment, the Sample Holder has a slot or port capable of interacting with an external source such as, for example, a hard drive, USB drive, memory card, smart phone, tablet, and the like.
In one embodiment, the Sample Holder is powered by an internal rechargeable battery, for example, a lithium ion rechargeable battery. In another embodiment, the Sample Holder is powered by an outside electrical source, such as a 5V, 12V, 110V, or 220V electrical source. In another embodiment, the Sample Holder is powered by a conventional battery. In another embodiment, the Sample Holder is powered by solar power using solar cells. In another embodiment, the Sample Holder is powered by two or more of the above power options.
In one embodiment, the Sample Holder can have means to connect to a computer, tablet, smartphone, or other device that can process data. The sample holder can have a connection port, such as a USB port or Thunderbolt port for such a connection. The Sample Holder can also have the ability to connect to other devices by means of Wifi, Bluetooth, or other non-wired connection.
In one embodiment, the Sample Holder has an interface that a user can use to interact with the sample holder, for example, an on/off switch, timer settings, test logging, a timer stop, and the like. In another embodiment, the Sample Holder has a touch screen that allows for a user to interact with the sample holder. In another embodiment, the touch screen is waterproof. In another embodiment, the Sample Holder has an audio and/or visual indicator indicating timer completion.
For a more detailed description of one preferred embodiment of the Sample Holder, turn to a consideration of
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Sample Holder 7 can be configured so that either the rows or columns of sample holders are removable. This allows the user flexibility for the testing of samples.
For a more detailed description of another preferred embodiment of the Sample Holder, turn to a consideration of
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This application claims priority to U.S. Patent Application No. 62/620,741 filed Jan. 23, 2018.
| Number | Date | Country | |
|---|---|---|---|
| Parent | 62620741 | Jan 2018 | US |
| Child | 16253499 | US |
