In Speculative Evolution, we envisioned how species could be further developed to increase their resilience based on scientific publications on synthetic biology, genetic engineering and robotics, and formulated text prompts to create AI-generated images using DALL-E. As a result, each speculative species in the environment has a backstory rooted in real-life scenarios.

Rana Japonica Frogs
2016	creation of color mutant frogs through artificial insemination Laboratory research by Masayuki et al., 2016
2054	sold mainly for observation of organ mechanisms and as ornamental frog

Lineage of the 50 species from a total of 76

- Samsung G955F, Android 9, Zurich, Switzerland (28-1)
  - Samsung G955F, Android 9, Zurich, Switzerland (28-1-1)
    - , Android 13, Penela, Portugal (28-1-1-1)
  - Samsung T720, Android 11, Del Viso, Argentina (28-1-2)
- Samsung T505, Android 11, Araranguá, Brazil (28-10)
  - Samsung T505, Android 11, Araranguá, Brazil (28-10-1)
    - Samsung G955U, Android 9, Xi'an, China (28-10-1-1)
- , Android 13, Benito Juarez, Mexico (28-11)
  - Samsung A325M, Android 13, Bahía Blanca, Argentina (28-11-1)
    - Samsung A325M, Android 13, Bahía Blanca, Argentina (28-11-1-1)
      - Samsung G950F, Android 9, São Paulo, Brazil (28-11-1-1-1)
- Samsung A325M, Android 13, Bahía Blanca, Argentina (28-12)
  - Samsung A127F, Android 12, Quezon City, Philippines (28-12-1)
- Samsung G950F, Android 9, São Paulo, Brazil (28-19)
  - Samsung G950F, Android 9, São Paulo, Brazil (28-19-1)
- Samsung G955F, Android 9, Zurich, Switzerland (28-2)
  - Samsung G955F, Android 9, Zurich, Switzerland (28-2-1)
- Samsung A127M, Android 13, Las Piedras, Uruguay (28-5)
  - Samsung G950F, Android 9, São Paulo, Brazil (28-5-1)
- Samsung T720, Android 11, Pilar, Argentina (28-8)
  - Samsung G955F, Android 9, Berlin, Germany (28-8-1)
    - Samsung G955F, Android 9, Berlin, Germany (28-8-1-1)
      - Samsung A215U, Android 12, Boardman, United States (28-8-1-1-1)
        Samsung T720, Android 11, Saltburn-by-the-Sea, United Kingdom (28-8-1-1-1-1)
        , Android 11, Sobral, Brazil (28-8-1-1-1-1-1)
        Samsung G950F, Android 9, São Paulo, Brazil (28-8-1-1-1-1-2)
        Samsung G950F, Android 9, São Paulo, Brazil (28-8-1-1-1-1-2-1)
        Samsung G950F, Android 9, São Paulo, Brazil (28-8-1-1-1-1-2-1-1)
        Samsung G950F, Android 9, São Paulo, Brazil (28-8-1-1-1-1-2-1-2)
        Samsung G986U1, Android 13, Monterrey, Mexico (28-8-1-1-1-1-2-1-2-1)
        Samsung G986U1, Android 13, Monterrey, Mexico (28-8-1-1-1-1-2-1-2-2)
        Samsung G950F, Android 9, São Paulo, Brazil (28-8-1-1-1-1-2-1-3)
        Samsung G955U, Android 9, Schaffhausen, Switzerland (28-8-1-1-1-1-2-1-3-1)
        , Android 11, Cebu City, Philippines (28-8-1-1-1-1-2-1-3-1-1)
        Samsung G955F, Android 9, Lucerne, Switzerland (28-8-1-1-1-1-3)
        Samsung G955F, Android 9, Lucerne, Switzerland (28-8-1-1-1-2)
        Samsung A055M, Android 14, Buenos Aires, Argentina (28-8-1-1-1-2-1)
  - Samsung G955F, Android 9, Lucerne, Switzerland (28-8-2)
    - Samsung G955F, Android 9, Lucerne, Switzerland (28-8-2-1)
- Samsung T720, Android 11, Pilar, Argentina (28-9)
  - Samsung T720, Android 11, Pilar, Argentina (28-9)
    - Samsung T720, Android 11, Jose C. Paz, Argentina (28-9-1-1)
  - Samsung T720, Android 11, Jose C. Paz, Argentina (28-9-2)
    - , Android 13, São Paulo, Brazil (28-9-2-1)
    - Huawei BTK, Android 12, Surabaya, Indonesia (28-9-2-2)
      - Samsung G986U1, Android 13, Monterrey, Mexico (28-9-2-2-1)
        Samsung G955F, Android 9, Lucerne, Switzerland (28-9-2-2-1-1)
    - Samsung G955U, Android 9, , China (28-9-2-3)
  - , Android 14, Wittmund, Germany (28-9-3)
  - Samsung G955U, Android 9, , China (28-9-4)

The first see-through frog created by breeding: description, inheritance patterns, and dermal chromatophore structure

Sumida, Masayuki et al. Scientific reports vol. 6 24431. 15 Apr. 2016, doi:10.1038/srep24431

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4832234/

Abstract

We have succeeded in creating see-through frogs from natural color mutants of the Japanese brown frog Rana japonica, which usually possesses an ochre or brown back; this coloration enables the organs, blood vessels, and eggs to be observed through the skin without performing dissection. We crossed two kinds of recessive color mutant (black-eyed and gray-eyed) frogs through artificial insemination, and F2 offspring produced frogs whose skin is translucent throughout the life cycle. Three kinds of dermal chromatophores—xanthophores, iridophores, and melanophores—are observed in a layered arrangement in the skin of wild-type frogs, but few chromatophores were present in the skin of the see-through frogs. The translucent skin enables observation of organ growth and cancer formation and progression in the animal, which can be monitored over its entire life without the need for dissection. See-through frogs thus provide a useful animal model for environmental, medical, and biological research.

See-through, two color mutant, and wild-type adult Rana japonica frogs.

Dorsolateral view of four types.
Ventral view of four types
See-through frog (frontal view)
See-through frog (ventral view)
See-through frog (ventrolateral view). (Scale bar 1 cm)