Proteomics of the Book: Difference between revisions
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==Proteomics in Biocodicology== | ==Proteomics in Biocodicology== | ||
Because the information gathered from proteomic techniques that determines the specific tissues on the sample, proteomics can be used to help determine certain stains on a book and also provide insight on how the physical document could have been used in the past."" | |||
Parchment analysis plays a major role in biocodicology because parchment paper is almost entirely made from organic molecules** as compared to other writing substrates where other inorganic** molecules are central to its role of development. With this logic, clay tables would be expected to have the least amount of cellular markers that could be extracted for analysis. Cheap and fast proteomic methods (i.e. eZooms)** are being used to identify the animal species that a specific parchment paper was made out of. Using the PQI** (Parchment Quality Index), these techniques can also shed light on the production quality of parchment samples."" | |||
==Current Challenges with Proteomics== | ==Current Challenges with Proteomics== | ||
==References== | ==References== | ||
Revision as of 21:04, 27 November 2020
Biocodicology is an extension of codicology. Both fields seek to answer questions about the book beyond its literary content. While codicology makes use of aspects of the book that we can see such as its material, binding style, or other physical aspects, biocodicology delves into remnants of the book that can't be seen with the naked eye. Biocodicology relies on the analysis of nucleic acids and amino acids that can be extracted from a books surface. Genomics is the study of DNA and RNA, molecules that have nucleic acid subunits. Proteomics is the study of proteins, molecules that have amino acid subunits.
The Field of Proteomics
Proteomics involves identifying all the proteins present in a given sample. Samples could range from organisms, biological assays, or physical objects (like books). Once the proteins have been identified, researchers can use that information to make inferences about the sample. For an organism this can take the form of its current state of health (during a check up when your doctor asks you to pee in a cup one of the things checked are your protein levels). Identifying proteins is only half of the endeavor, it is also equally important to analyze the quantity of the proteins in a sample. Both the types and quantity of protein present are necessary for one to make an important inference.
Proteins
Proteins have a primary structure, which consist of a string of its amino acids in the order that they were placed. This primary structure more or less determines how a protein folds/forms, leading to its shape, which then determines its function. Slight changes in the primary sequence of the same protein can help people using proteomic techniques to discriminate between different species and allow for specific species identification.
Unlike DNA, which remains the same regardless of cell type within an organism, proteins have tissue specificity. Protein levels are are also susceptible to environmental factors. This means that one can not only identify the species but also the specific biological tissue.
Proteomics in Biocodicology
Because the information gathered from proteomic techniques that determines the specific tissues on the sample, proteomics can be used to help determine certain stains on a book and also provide insight on how the physical document could have been used in the past.""
Parchment analysis plays a major role in biocodicology because parchment paper is almost entirely made from organic molecules** as compared to other writing substrates where other inorganic** molecules are central to its role of development. With this logic, clay tables would be expected to have the least amount of cellular markers that could be extracted for analysis. Cheap and fast proteomic methods (i.e. eZooms)** are being used to identify the animal species that a specific parchment paper was made out of. Using the PQI** (Parchment Quality Index), these techniques can also shed light on the production quality of parchment samples.""