The present invention is related to the field of bio/chemical sampling, sensing, assays and applications. Particularly, the present invention is related to how to make the sampling/sensing/assay become simple to use, fast to results, highly sensitive, easy to use, using tiny sample volume (e.g. 0.5 uL or less), operated by a person without any professionals, reading by mobile-phone, or low cost, or a combination of them.

The present invention is related to the field of bio/chemical sampling, sensing, assays and applications. Particularly, the present invention is related to how to make the sampling/sensing/assay become simple to use, fast to results, highly sensitive, easy to use, using tiny sample volume (e.g. 0.5 uL or less), operated by a person without any professionals, reading by mobile-phone, or low cost, or a combination of them.

A Fisher's exact test calculation apparatus includes: a condition storage 1 that has stored therein a condition for determining whether a result of Fisher's exact test corresponding to input is significant or not, the input being frequencies in a summary table; and a calculation unit 2 that obtains the result of Fisher's exact test corresponding to the frequencies in the summary table by inputting the frequencies in the summary table to the condition read from the condition storage 1.

Nick-based methods, devices, and systems for nick-based data storage in a deoxyribonucleic acid (DNA) sequence are disclosed. Digital information is encoded in a register of at least one copy of a double-stranded DNA sequence having a plurality of nickable positions. The data is translated into a sequence of values from a nick alphabet that is subsequently mapped to the plurality of nickable positions, and the DNA sequence is nicked according to the mapped values. Because the digital information is encoded as a series of nicked and non-nicked positions of a double-stranded DNA sequence, the nucleotide sequence of the DNA can be non-synthetic, or “native” DNA.

Nick-based methods, devices, and systems for nick-based data storage in a deoxyribonucleic acid (DNA) sequence are disclosed. Digital information is encoded in a register of at least one copy of a double-stranded DNA sequence having a plurality of nickable positions. The data is translated into a sequence of values from a nick alphabet that is subsequently mapped to the plurality of nickable positions, and the DNA sequence is nicked according to the mapped values. Because the digital information is encoded as a series of nicked and non-nicked positions of a double-stranded DNA sequence, the nucleotide sequence of the DNA can be non-synthetic, or “native” DNA.

A method of storing information using monomers such as nucleotides is provided including converting a format of information into a plurality of bit sequences of a bit stream with each having a corresponding bit barcode, converting the plurality of bit sequences to a plurality of corresponding oligonucleotide sequences using one bit per base encoding, synthesizing the plurality of corresponding oligonucleotide sequences on a substrate having a plurality of reaction locations, and storing the synthesized plurality of corresponding oligonucleotide sequences.

A method of storing information using monomers such as nucleotides is provided including converting a format of information into a plurality of bit sequences of a bit stream with each having a corresponding bit barcode, converting the plurality of bit sequences to a plurality of corresponding oligonucleotide sequences using one bit per base encoding, synthesizing the plurality of corresponding oligonucleotide sequences on a substrate having a plurality of reaction locations, and storing the synthesized plurality of corresponding oligonucleotide sequences.

The present invention comprises the capture and display of arthropod, human and arthropod-based metadata, which is capable of tracking and displaying the metadata, which is time and location-based, in order to show migration paths of arthropods and/or the diseases they have the potential to carry. This real-time view can help predict future arthropod and disease based on various scenarios such as, but not limited to: increased exposure based on the following: a user's geo-location, date and/or time of year, carrier type, etc. These variables can then assist with the education, awareness and potential prevention of disease.

The present invention comprises the capture and display of arthropod, human and arthropod-based metadata, which is capable of tracking and displaying the metadata, which is time and location-based, in order to show migration paths of arthropods and/or the diseases they have the potential to carry. This real-time view can help predict future arthropod and disease based on various scenarios such as, but not limited to: increased exposure based on the following: a user's geo-location, date and/or time of year, carrier type, etc. These variables can then assist with the education, awareness and potential prevention of disease.

Disclosed herein are methods and systems for storing data and/or information on nucleic acid molecules, storing the nucleic acid molecules, and retrieving the data and/or information. These methods and systems have broad applications for data storage, including in improving the efficiency and accuracy of retrieving data.