AIMS and SCOPE

AIMS AND SCOPE:

"Advances in Genetic Engineering" is a peer-reviewed, open-access journal that publishes original research articles, reviews, and commentaries in the field of genetic engineering. The journal aims to disseminate the latest research findings, methods, and tools in genetic engineering to the scientific community.

The scope of the journal covers the following topics:

  1. Gene editing: CRISPR/Cas9 system, ZFNs, TALENs, RNA-guided nucleases, homing endonucleases, and other gene-editing tools and methods.
  2. Recombinant DNA technology: Gene cloning, gene expression, DNA sequencing, synthetic biology, genome engineering, and other related techniques.
  3. Genetic modification: Transgenic organisms, genetically modified organisms (GMOs), gene therapy, gene silencing, and other genetic modification techniques.
  4. Genetic diversity and evolution: Genetic diversity, population genetics, phylogenetics, evolutionary genetics, and comparative genomics.
  5. Genomics and transcriptomics: Whole-genome sequencing, gene expression profiling, transcriptome analysis, functional genomics, and other genomic and transcriptomic methods.
  6. Molecular biology and biochemistry: Protein engineering, enzymology, metabolic engineering, synthetic biology, and other molecular biology and biochemistry techniques.
  7. Systems and computational biology: Systems biology, computational modeling, network analysis, bioinformatics, and other computational and theoretical approaches to genetic engineering.
  8. Applications of genetic engineering: Agriculture, biotechnology, medicine, environmental science, and other applied fields of genetic engineering.

The journal welcomes submissions from all areas of genetic engineering, including basic research, translational research, and applied research.

KEYWORDS/SUB-TOPICS:

  1. CRISPR/Cas9 system
  2. ZFNs
  3. TALENs
  4. RNA-guided nucleases
  5. Homing endonucleases
  6. Gene cloning
  7. Gene expression
  8. DNA sequencing
  9. Synthetic biology
  10. Genome engineering
  11. Transgenic organisms
  12. GMOs
  13. Gene therapy
  14. Gene silencing
  15. Genetic diversity
  16. Population genetics
  17. Phylogenetics
  18. Evolutionary genetics
  19. Comparative genomics
  20. Whole-genome sequencing
  21. Gene expression profiling
  22. Transcriptome analysis
  23. Functional genomics
  24. Protein engineering
  25. Enzymology
  26. Metabolic engineering
  27. Systems biology
  28. Computational modeling
  29. Network analysis
  30. Bioinformatics
  31. Agriculture
  32. Biotechnology
  33. Medicine
  34. Environmental science
  • Applied fields of genetic engineering
  1. Genetic engineering in cancer research
  • CRISPR-Cas system in gene therapy
  • Genome editing in agriculture
  • Gene editing in rare diseases
  1. CRISPR-mediated gene drives
  2. Synthetic biology for biomanufacturing
  3. Gene therapy for inherited disorders
  4. CRISPR for RNA editing
  5. Epigenetic modifications
  6. Proteomics
  7. Transcriptomics
  8. Cell biology
  9. Molecular genetics
  10. Plant genetic engineering
  11. Genome-wide association studies
  12. Single-cell sequencing
  13. Genetically modified food
  • Genetic engineering in regenerative medicine
  1. Genome editing ethics
  2. Genetic engineering patents
  • Drug discovery
  1. Viral vectors in gene therapy
  2. Stem cell engineering
  3. Bioprocessing
  4. Industrial biotechnology
  5. DNA damage and repair
  6. Genetic engineering in neurodegenerative diseases
  7. Genome editing in plants
  8. Genome editing in animals
  • Genome editing in humans
  1. Gene therapy
  • CRISPR/Cas9 system
  • Zinc-finger nucleases (ZFNs)
  • TALENs (Transcription Activator-Like Effector Nucleases)
  1. Synthetic biology
  2. Gene drive
  3. Synthetic gene circuits
  • Genome-wide association studies (GWAS)
  1. Epigenetics
  2. Epigenetic inheritance
  • RNA editing
  1. RNA interference (RNAi)
  2. Non-coding RNAs
  3. Circular RNAs (circRNAs)
  4. Long non-coding RNAs (lncRNAs)
  5. MicroRNAs (miRNAs)
  6. Small interfering RNAs (siRNAs)
  • RNA vaccines
  1. RNA sequencing
  2. Single-cell sequencing
  • Metagenomics
  1. Structural genomics
  2. Comparative genomics
  3. Functional genomics
  4. Proteomics
  5. Protein engineering
  6. Protein-protein interactions
  • Protein structure prediction
  1. Protein folding
  2. Protein crystallization
  • Antibody engineering
  1. Immunotherapy
  2. Vaccinology
  3. Pharmacogenomics
  4. Personalized medicine
  5. Precision medicine
  6. Cancer genomics
  7. Cancer immunotherapy
  8. Gene expression analysis
  9. Transcriptomics
  10. Metabolomics
  11. Lipidomics
  12. Glycomics
  13. High-throughput screening
  14. CRISPR screens
  15. Drug discovery
  16. Bioinformatics
  17. Computational biology
  18. Systems biology
  19. Network biology
  20. Machine learning
  21. Artificial intelligence
  22. Big data
  23. Data mining
  24. Data visualization
  25. Biostatistics
  26. Mathematical modeling
  27. Mathematical biology
  28. Evolutionary biology
  29. Phylogenetics
  30. Population genetics
  31. Synthetic lethality
  32. Mutagenesis
  33. DNA repair
  34. Telomeres
  35. Telomerase
  36. Aging
  37. Senescence
  38. Regenerative medicine
  39. Stem cell biology
  40. Cell reprogramming
  41. Organoid culture
  42. Tissue engineering
  43. Bioethics
  44. Intellectual property
  45. Gene patents
  46. Genetically modified organisms (GMOs)
  47. Gene drives in the wild
  48. Synthetic biology regulation
  49. Gene therapy regulation
  50. CRISPR/Cas9 regulation
  51. Personalized medicine regulation
  52. Privacy concerns in genomics
  53. Clinical trials in genomics
  54. Health disparities in genomics
  55. Agriculture and genomics
  56. Sustainable agriculture
  57. Biofuels
  58. Environmental genomics
  59. Bioremediation
  60. Synthetic biology and biosecurity
  61. Biotechnology and industry
  62. Patent law and biotechnology
  63. Agricultural biotechnology
  64. Medical biotechnology
  65. Industrial biotechnology
  66. Green biotechnology
  67. Marine biotechnology
  68. Bio manufacturing
  69. Bioprocessing
  70. Industrial fermentation
  71. Enzyme engineering
  72. Biomaterials
  73. Biodegradable plastics
  74. Food biotechnology
  75. Food safety and genomics
  76. GMO labeling
  77. Nano biotechnology
  78. Nano medicine
  79. Nanoparticles
  80. Nano toxicology
  81. Ethics of nanotechnology
  82. Stem cell therapy
  83. Reproductive biotechnology
  84. In vitro fertilization
  85. RNAi
  86. Site-directed mutagenesis
  87. Transgenic animals
  88. Transgenic plants
  89. Synthetic biology
  90. DNA synthesis
  91. Genetic circuits
  92. RNA sequencing
  93. Epigenetics
  94. CRISPR
  95. Genome editing
  96. Functional genomics
  97. Proteomics
  98. Metabolomics
  99. Bioinformatics
  100. Computational biology
  101. Systems biology
  102. Gene expression analysis
  103. Chromatin remodeling
  104. DNA repair mechanisms.

Overall, Advances in Genetic Engineering aims to provide a platform for researchers and scientists from various fields to publish their original research, review articles, and commentaries on genetic engineering, its latest advancements, and applications. The journal emphasizes the importance of promoting and disseminating knowledge in this rapidly evolving field to facilitate further developments and applications of genetic engineering in various industries, including agriculture, medicine, biotechnology, and environmental science. The wide range of topics covered in the journal ensures that researchers from various fields and disciplines can find relevant and valuable information related to genetic engineering. The journal also aims to promote ethical and responsible research practices in genetic engineering, keeping in mind the potential social, economic, and environmental implications of genetic engineering research and applications.