Submitted:
05 July 2026
Posted:
07 July 2026
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Abstract
Keywords:
1. Introduction
2. Materials and Methods
3. Results and Discussion
3.1. Conventional Breeding: Methodology and Constraints
3.2. Speed Breeding: System, Principles and Validated Protocols
3.2.1. Generational Throughput and Validated Crops
3.2.2. Integration with Molecular Tools
3.3. Critical Assessment of Speed Breeding
3.3.1. Genotype × Environment Interaction
3.3.2. Trait Coverage and Phenotypic Fidelity
3.3.3. Infrastructure, Cost and Equity
3.3.4. Biological Validity of Accelerated Generations
3.3.5. Integration, Not Replacement
3.4. New Genomic Techniques versus GMOs: Complementarity with Conventional and Speed Breeding
4. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Abbreviations
References
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| Source | Type | Principal Focus and Key Reported Findings | Generations/Year Reported |
|---|---|---|---|
| Blinkov et al. [5], Front. Plant Sci. | Review | Comprehensive systematisation of all factors (photoperiod, light spectrum/intensity, temperature, CO2, vernalisation, mineral nutrition, substrate volume, tiller removal, growth regulators) influencing SB across ~30 crops; consolidates embryo-culture and forced-drying protocols and genetic-engineering approaches. | 2–6 (crop-dependent); up to 7 in chickpea |
| Watson et al. [4], Nat. Plants | Primary/protocol | Founding demonstration of SB at scale; 22 h/2 h photoperiod with immature-seed harvest; first report of 6 generations/year in wheat, barley, chickpea and pea, 4 in rapeseed; established growth-chamber, glasshouse and low-cost-room implementations. | 4–6 |
| Ghosh et al. [14], Nat. Protoc. | Protocol | Detailed, step-by-step methodology accompanying Watson et al. [4]; specifies PAR range (400–700 nm), dawn/dusk simulation, and immature-seed drying/germination procedures. | 4–6 |
| Jähne et al. [9], Theor. Appl. Genet. | Primary/protocol | First validated LED-controlled SB protocol for short-day crops; blue-enriched, far-red-deprived spectrum at 10 h photoperiod; demonstrates strong genotype- and species-specific response to far-red light (positive in rice/amaranth, neutral in soybean). | Soybean 5; rice and amaranth flowering accelerated 8–20 days by far-red light |
| Pandey et al. [2], Plant Breed. | Review | Frames SB as one of several accelerated strategies; emphasises integration with MAS, genomic selection, pollen-based selection and genome editing; tabulates SB applications across 19 crop species. | 2–8 (crop-dependent) |
| Chaudhary and Sandhu [8], Euphytica | Review | Historical account tracing SB to 1980s USDA and NASA work; compiles list of SB-derived cultivar releases (2014–2021) and direct cost data (>50% of SB cost attributable to lighting/temperature control). | 4–7.6 depending on crop and protocol |
| Potts et al. [7], Crops | Review | Traces SB lineage to 19th-century carbon-arc-lamp experiments; situates SB alongside single-plant selection and SSD; reviews high-density planting as a low-cost acceleration strategy and surveys infrastructure barriers in developing countries. | 4–7 (crop-dependent); up to 8 in cowpea |
| Samantara et al. [13], Biology | Review | Perspective review emphasising SB’s alignment with single-plant selection and SSD, and its capacity to exploit allelic diversity from landraces and wild progenitors; surveys applications in genetic mapping, genetic modification and trait stacking. | Crop-dependent |
| Note: generations/year figures are as reported in the cited source and reflect different genotype panels, facility specifications and harvest criteria; direct comparison across sources should account for these differences. | |||
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