Talk:List of omics topics in biology

1. Genomics: Study of the genome, the complete set of genes in an organism.

2. Proteomics: Study of the proteome, the entire collection of proteins in an organism's cells.

3. Metabolomics: Study of metabolism and the function and interactions of metabolic breakdown products, or metabolites.

4. Transcriptomics: Study of the full complement of RNA in an organism's cells.

5. Lipidomics: Study of lipids and pathways involved in lipid signaling.

6. Epigenomics: Study of the chemical modifications to DNA and histone proteins that regulate gene expression without changing the DNA sequence.

7. Glycomics: Study of the glycome, the complete set of sugars, or glycans, in an organism.

8. Phenomics: Study of phenomes, the physical and biochemical traits of organisms.

9. harmacogenomics: Study of how genes affect a person's response to drugs.

10. Toxicogenomics: Study of the effects of toxic chemicals on the genome and gene expression.

11. Nutrigenomics: Study of the interactions between nutrition and genes.

12. Microbiomics: Study of microbial communities (microbiota) and their collective genomes (microbiome).

13. Viromics: Study of the viral community and their interactions within a host organism.

14. Exposomics: Study of the totality of human environmental exposures and their effects on health.

15. Connectomics: Study of neural connections in the brain.

16. Immunomics: Study of the immune system on an omic scale.

17. Interactomics: Study of the relationships and interactions between proteins and other molecules.

18. Fluxomics: Study of the rates of metabolic reactions in a biological system.

19. *Phosphoproteomics: Study of phosphorylated proteins and their roles in cell signaling and function.

20. Splicomics: Study of RNA splicing and its variations across different tissues or conditions.

21. Secretomics: Study of the secretome, the entire set of proteins secreted by a cell, tissue, or organism.

22. Degradomics: Study of the proteolytic enzymes (proteases) and their substrates.

23. Ubiquitinomics: Study of ubiquitin and ubiquitin-like protein modifications on other proteins.

24. Metallomics: Study of the role of metal ions in biological systems.

25. Redoxomics**: Study of redox states and the roles of reactive oxygen species in cellular processes.

26. Volatilomics**: Study of volatile organic compounds produced by living organisms.

27. Theranostics**: A combination of therapeutics and diagnostics, often studied at an omics level.

28. Cytomics**: Study of the cell and its functions at a molecular level.

29. Sensomics**: Study of sensory perception and the associated molecules and pathways.

30. Foodomics**: Application of omics technologies in food and nutrition research.

31. Chronomics**: Study of biological rhythms and their molecular mechanisms.

32. Peptidomics**: Study of peptides, their structures, functions, and roles in biology.

33. Ecogenomics**: Study of the genetic composition of ecological communities and their interactions with the environment.

34. Pathogenomics**: Study of the genomes of pathogens to understand their biology and interaction with hosts.

35. Nucleomics**: Study of the nuclear components of cells, including chromatin and nuclear bodies.

36. Single-cell omics**: Study of the omics data at the single-cell level to understand cellular heterogeneity.

37. Oncomics**: Study of cancer-related genes, proteins, and pathways.

38. Biomechanics omics**: Study of the mechanical properties of biological molecules and structures.

39. Symbiomics**: Study of symbiotic relationships at the molecular level.

40. Interactomics**: Study of molecular interactions in biological systems, including protein-protein, protein-DNA, and protein-RNA interactions.

41. Paleomics**: Study of ancient biological materials through omics technologies.

42. Methylomics**: Study of DNA methylation patterns across the genome.

43. Toxicoepigenomics**: Study of the effects of environmental toxins on epigenetic modifications.

44. Neurogenomics**: Study of the genetic basis of nervous system structure and function.

45. Immunopeptidomics**: Study of peptides presented by the immune system, particularly those bound to MHC molecules.

46. Phytomics**: Study of plant genomes and their interactions with the environment.

47. Autoimmunomics**: Study of the molecular mechanisms underlying autoimmune diseases.

48. Agrigenomics**: Application of genomics in agriculture to improve crop and livestock production.

49. Thermogenomics**: Study of the genetic basis of thermoregulation and heat production in organisms.

50. Biome omics**: Study of the genetic and molecular makeup of whole biomes (large ecological areas).

51. Metagenomics**: Study of genetic material recovered directly from environmental samples, bypassing the need for isolating and culturing individual species.

52. Astrobiomics**: Study of potential life and biological molecules in space environments.

53. Connectomics**: Study of the comprehensive maps of neural connections in the brain.

54. Kinomics**: Study of kinases and their roles in cellular signaling.

55. Phenomics**: Study of phenotypes on an omics scale, capturing the physical and biochemical traits of organisms.

56. Glycoproteomics**: Study of glycoproteins, which are proteins with carbohydrate groups attached.

57. Nutriproteomics**: Study of the effects of nutrients on the proteome.

58. Epitranscriptomics**: Study of chemical modifications on RNA molecules and their impact on gene expression and function.

59. Glycolipidomics**: Study of glycolipids, complex molecules consisting of carbohydrates and lipids.

60. Endocrinomics**: Study of the endocrine system and hormone-related omics data.

61. Psychomics**: Study of the molecular basis of psychological and psychiatric conditions.

62. Interactomics**: Comprehensive study of all molecular interactions in a cell.

63. Distributomics**: Study of the distribution patterns of molecules within cells or organisms.

64. Pangenomics**: Study of the complete set of genes within a species, including core and accessory genes.

65. Adaptomics**: Study of adaptive changes in organisms at the molecular level.

66. Seromics**: Study of serum proteins and metabolites.

67. Neuroproteomics**: Study of the proteome of the nervous system.

68. Phytochemomics**: Study of the complex chemical compounds in plants.

69. Agingomics**: Study of the molecular and genetic factors involved in aging.

70. Radiogenomics**: Study of the relationship between genetic variation and response to radiation therapy.

71. Immunogenomics**: Study of the genetic basis of immune system function and diversity.

72. Biogeomics**: Study of the genomic basis of biodiversity and ecosystem function.

73. Virogenomics**: Study of viral genomes and their interactions with host organisms.

74. Dermomics**: Study of the molecular and genetic aspects of skin biology.

75. Allergomics**: Study of the molecular and genetic basis of allergic reactions.

76. Plantomics**: Comprehensive study of plant biology using omics approaches.

77. Oceanomics**: Study of marine organisms and ecosystems using omics technologies.

78. Parasite genomics**: Study of the genomes of parasitic organisms.

79. Aquaculture omics**: Application of omics technologies to improve aquaculture practices.

80. Epigenomics**: Study of the complete set of epigenetic modifications on the genetic material of a cell.

81. Pathophysiomics**: Study of the molecular and cellular mechanisms of disease processes.

82. Quantum omics**: Study of quantum mechanical properties of biological molecules and their influence on biological functions.

83. Thermogenomics**: Study of the genetic basis of temperature regulation in organisms.

84. Chronomics**: Study of biological rhythms and their molecular bases.

85. Syntheomics**: Study of synthetic biology approaches using omics data to design and construct new biological parts, devices, and systems.

86. Holobiont omics**: Study of the omics data of a host and its associated microbiota as a single ecological unit.

87. Ecophysiomics**: Study of the interactions between the physiological functions of organisms and their environment at an omics level.

88. Resistomics**: Study of antibiotic resistance genes and their mechanisms.

89. Aptameromics**: Study of aptamers, short DNA or RNA molecules that bind to specific targets, and their applications.

90. Virulomics**: Study of virulence factors and mechanisms of pathogenicity in microbes.

91. Mycomics**: Study of fungal genomes and their biological functions.

92. Photomics**: Study of the interaction between light and biological systems.

93. Nanonics**: Study of nanomaterials and their interactions with biological systems using omics approaches.

94. Allergenomics**: Study of allergens and the molecular basis of allergic responses.

95. Xenobiomics**: Study of the effects of foreign substances (xenobiotics) on biological systems.

96. Physiomics**: Study of the physiological aspects of biological systems at an omics scale.

97. Psychogenomics**: Study of the genetic and molecular basis of psychological traits and disorders.

98. Methylomics**: Study of DNA methylation patterns and their effects on gene expression.

99. Cardiomics**: Study of the molecular and genetic basis of cardiovascular function and diseases.

100. Degradomics**: Study of the proteolytic processes and protein degradation pathways.

101. Astrobiomics**: Study of the potential for life and biological processes in extraterrestrial environments.

102. Geonomics**: Study of the genetic basis of geological and geobiological processes.

103. Radiomics**: Study of the quantifiable features of medical images and their association with clinical outcomes.

104. Biome omics**: Study of the genetic, molecular, and ecological interactions within biomes.

105. Allosteromics**: Study of allosteric sites and their regulatory roles in protein function.

106. Biothermodynamics**: Study of the thermodynamic properties of biological molecules and systems using omics approaches.

107. Anthropomics**: Study of human diversity and evolution using omics data.

108. Connectomics**: Study of neural connections within the brain and nervous system.

109. Autophagomics**: Study of the autophagy process at an omics level.

110. Photogenomics**: Study of the effects of light on gene expression and cellular functions.

111. Aeroomics**: Study of airborne biological particles and their impact on health and environment.

112. Epitranscriptomics**: Study of chemical modifications on RNA molecules and their impact on gene expression and function.

113. Radiogenomics**: Study of the relationship between genomic features and response to radiation therapy.

114. Nephromics**: Study of the kidneys and their functions at a molecular level.

115. Dermatomics**: Study of the skin and its molecular composition and functions.

116. Xenomics**: Study of the effects and interactions of foreign genetic material introduced into an organism.

117. MicroRNAomics**: Study of microRNAs and their roles in regulating gene expression.

118. Synthetic omics**: Study and design of synthetic biological systems using omics data.

119. Environomics**: Study of the interactions between organisms and their environment using omics technologies.

120. Paleomics**: Study of ancient biological materials and their molecular information.

121. Regulomics**: Study of regulatory networks and their roles in gene expression.

122. Pathobiomics**: Study of disease pathways and mechanisms at an omics scale.

123. Evolvomics**: Study of evolutionary processes and patterns using omics data.

124. Thermobiomics**: Study of the effects of temperature on biological molecules and systems.

125. Circadiomics**: Study of circadian rhythms and their molecular underpinnings.

126. Nanomics**: Study of nanoscale biological processes and materials.

127. Metaproteomics**: Study of the collective protein content in environmental samples.

128. Biomechanics omics**: Study of the mechanical properties of biological molecules and systems.

129. Cancer omics**: Study of the molecular basis of cancer, including oncogenomics and cancer proteomics.

130. Synthetic biology omics**: Application of omics technologies to design and construct new biological parts, devices, and systems.

131. Gutomics**: Study of the gut microbiome and its interactions with the host.

132. Nutrigenomics**: Study of the relationship between nutrition and the genome.

133. Plant omics**: Comprehensive study of plant biology using omics approaches.

134. Infectomics**: Study of the molecular mechanisms of infectious diseases.

135. Microbiomics**: Study of microbial communities and their functions.

136. Sexomics**: Study of the molecular basis of sex differences in biology.

137. Biomechanomics**: Study of the interaction between mechanical forces and biological systems.

138. Neurogenomics**: Study of the genetic basis of neurological functions and disorders.

139. Omeomics**: Study of the relationships and interactions between different omes (genome, proteome, etc.).

140. Immunotranscriptomics**: Study of the transcriptome of immune cells.

141. Nervomics**: Study of the nervous system and its molecular components.

142. Embryomics**: Study of the molecular and genetic processes during embryonic development.

143. Agingomics**: Study of the molecular basis of aging.

144. Photoproteomics**: Study of proteins involved in light sensing and response.

145. Hematomics**: Study of the molecular composition and function of blood.

146. Biophotonics omics**: Study of the interaction of light with biological materials at an omics level.

147. Anatomics**: Study of the molecular basis of anatomical structures.

148. Mycobiomics**: Study of fungal communities and their interactions with the host or environment.

149. Pathogenomics**: Study of the genomes of pathogens.

150. Symbiomics**: Study of symbiotic relationships at the molecular level.

151. Aquomics**: Study of aquatic organisms and their molecular biology.

152. Bacteriomics**: Study of bacteria and their genomes.

153. Biomarkeromics**: Study of biomarkers using omics technologies for disease detection and monitoring.

154. Cardiomics**: Study of the cardiovascular system at a molecular level.

155. Cellomics**: Study of cell structure, function, and behavior using high-throughput methods.

156. Chemogenomics**: Study of the genomic response to chemical compounds.

157. Cryomics**: Study of biological molecules and systems under low-temperature conditions.

158. Distributomics**: Study of the spatial distribution of molecules within cells or tissues.

159. Ecosystem omics**: Study of entire ecosystems using omics approaches.

160. Energetics omics**: Study of the energy flow and metabolism in biological systems.

161. Gastroomics**: Study of the gastrointestinal system and its microbiota.

162. Genetherapeutics omics**: Study of gene therapy approaches and their effects at an omics level.

163. Hormonomics**: Study of hormones and their molecular pathways.

164. Hydratomics**: Study of the hydration state of biological molecules and systems.

165. Inflamomics**: Study of inflammation and its molecular pathways.

166. Metalloproteomics**: Study of metalloproteins and their roles in biology.

167. Morphomics**: Study of the shape and structure of organisms and their molecular basis.

168. Nervomics**: Study of the nervous system and its molecular composition.

169. Neurochemomics**: Study of the chemical processes in the nervous system.

170. Nutriomics**: Study of the interactions between nutrients and the genome.

171. Ocularomics**: Study of the eye and its molecular biology.

172. Optogenomics**: Study of the genetic basis of light perception and response.

173. Organomics**: Study of specific organs at a molecular level.

174. Parasitomics**: Study of parasites and their interactions with hosts.

175. Pathophenomics**: Study of disease phenotypes and their molecular basis.

176. Pharmacomics**: Study of drugs and their effects on the genome and proteome.

177. Polyomics**: Study of the complex interactions between multiple omes (genome, proteome, etc.).

178. Psychomics**: Study of the molecular basis of psychological traits and disorders.

179. Pulmonomics**: Study of the lungs and respiratory system at a molecular level.

180. Reproductomics**: Study of reproductive systems and their molecular biology.

181. Respiromics**: Study of the respiratory system and its molecular functions.

182. Selenomics**: Study of the role of selenium in biology.

183. Sexomics**: Study of the molecular basis of sex differences and sexual development.

184. Spatiomics**: Study of the spatial distribution of molecules within biological systems.

185. Sportomics**: Study of the molecular basis of sports performance and physical activity.

186. Stemcellomics**: Study of stem cells and their molecular properties.

187. Stromomics**: Study of the stroma, the supportive tissue in organs, and its molecular components.

188. Subcellomics**: Study of the molecular composition of subcellular compartments.

189. Synaptomics**: Study of synapses and their molecular components.

190. Toxinomics**: Study of toxins and their effects on the genome and proteome.

191. Traumomics**: Study of the molecular basis of trauma and injury.

192. Vascularomics**: Study of the vascular system and its molecular biology.

193. Virosomomics**: Study of the structure and function of viral particles.

194. Zoonomics**: Study of zoonotic diseases and their molecular basis.