“Introduction: Cannabis sativa L. is an annual herbaceous plant with a long history of multipurpose use, including food, textile, and medicinal applications. The progressive legalization in several countries has significantly increased its large-scale cultivation, consequently generating a substantial amount of biomass waste. This scenario calls for innovative and sustainable strategies to valorize Cannabis residues, aiming at promoting the circular economy and technological innovation.

Materials and methods: An integrative review was conducted following Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines. Systematic searches were performed in SCOPUS, PubMed, and SciELO, complemented by specialized platforms such as CANNUSE and CONSENSUS. Peer-reviewed empirical studies were included if they addressed the utilization, reutilization, or recycling of C. sativa by-products or residues for the development of industrial products, processes, or inputs. The analysis considered thematic and commercial domains, geographic origin, and biomass type.

Results: A total of 262 studies were included, with 144 retrieved from indexed databases and 118 from alternative methods. The most commonly explored residues were stems (48.2%), seeds (21.0%), and postextraction residuum (9.7%). The majority of applications were related to technology and innovation (37.5%) and industrial sectors (36.9%). A total of 328 technologies were identified, highlighting applications such as textile fibers, bioplastics, biofuels, functional foods, adsorbents, and natural cosmetics. Italy, China, and the United States led in scientific production. Leaves (7.0%) and roots (0.9%) were significantly underexplored despite their bioactive potential.

Discussion: The findings demonstrate a growing global interest in the valorization of C. sativa residues, with promising applications in bioeconomy, regenerative agriculture, phytoremediation, and energy transition. The integration of traditional knowledge and green technologies is a key strategy to enhance sustainability and socioterritorial inclusion. Nonetheless, regulatory gaps and a lack of robust clinical and toxicological studies limit the use of by-products in food and feed chains.

Conclusion: The residual biomass of C. sativa holds high technological, environmental, and economic value. Strategic valorization demands regulatory advancement, the development of green technologies, and the strengthening of multidisciplinary research. Industrial Cannabis emerges as a driver of ecological, social, and economic transformation toward sustainable circular production systems.”

https://pubmed.ncbi.nlm.nih.gov/41652844

https://journals.sagepub.com/doi/10.1177/25785125261421439

“Cannabis sativa, long established as a cornerstone of the pharmaceutical and industrial fiber markets, represents a radical and underexplored platform for renewable energy innovation.

In this Hypothesis and Theory framework, we introduce a novel, patented (Provisional Patent No. 63916615) dual-use bio-refinery paradigm. This model harnesses engineered cannabis photosynthesis to drive green hydrogen production without compromising its established value as a high-yield medicinal crop.

By strategically redirecting photosynthetic electron flow toward oxygen-protected hydrogenase activity, it is possible to generate molecular hydrogen at commercially relevant scales while maintaining plant viability.

Unique to this model is the ability to leverage over $10 billion in existing controlled-environment agriculture (CEA) infrastructure, bypassing the capital-intensive barriers that have hindered traditional algal biohydrogen systems. We outline a tripartite circular economy strategy that integrates hydrogen capture during the vegetative phase with the subsequent harvest of therapeutic cannabinoids and industrial biomass.

This convergence of synthetic biology, clean energy, and biomedicine positions cannabis as a uniquely versatile multipurpose crop capable of fueling both the pharmaceutical industry and the global transition to a sustainable hydrogen economy.”

https://pubmed.ncbi.nlm.nih.gov/42245109

“The global transition toward a net-zero carbon economy necessitates the development of scalable, carbon-negative energy sources. While hydrogen (H₂) is a premier clean energy carrier, biological production methods have traditionally struggled with economic viability due to low feedstock density and high infrastructure costs. We propose that Cannabis sativa, a crop already optimized for high-density biomass and metabolic output, serves as the ideal biological “factory” to overcome these hurdles.”

“Cannabis sativa stands at the intersection of the most disruptive shifts in modern industry: the legalization of medicinal biotechnologies and the urgent need for carbon-negative energy transition.

By adopting this patented dual-use framework, we can transform one of the world’s most valuable crops into an engine for a sustainable, hydrogen-powered future.”

“Collaborative frameworks between synthetic biologists, agricultural engineers, and regulatory bodies will be essential to advance this platform toward commercial viability.”

https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2026.1833491/full

“The search for modulators of melanogenesis with improved biological compatibility remains an active area of investigation, as existing tyrosinase (TYR) inhibitors are often limited by low potency, instability, or cytotoxicity.

Here, we investigated CBD-TSC₁, a cannabidiol-based thiosemicarbazone derivative, as a TYR-targeting scaffold.

Structural characterization confirmed a single, stable E-isomer, and pKa profiling together with kinetic analyses indicated reversible mixed-type inhibition of human TYR, involving interactions with both free enzyme and enzyme-substrate complexes. CBD-TSC₁ exhibited higher inhibitory activity than CBD and kojic acid under the tested conditions while maintaining low cytotoxicity in G361 melanoma and HaCaT keratinocyte cell lines. In addition, CBD-TSC₁ reduced intracellular oxidative stress at low micromolar concentrations. In zebrafish larvae, treatment with CBD-TSC₁ resulted in a dose-dependent reduction in melanin content, comparable to that of kojic acid under identical experimental conditions, supporting an association between thiosemicarbazone modification and the observed biological activity.

Overall, CBD-TSC₁ demonstrated consistent activity across biochemical, cellular, and zebrafish-based assays under the tested conditions. Although the mechanistic relationship between TYR inhibition, redox modulation, and melanogenesis regulation remains to be fully clarified, the present findings support further investigation of cannabidiol-based thiosemicarbazone derivatives as modulators of TYR-related pathways.”

https://pubmed.ncbi.nlm.nih.gov/42235859

“CBD-TSC₁ is a novel cannabidiol-thiosemicarbazone hybrid with dual anti-melanogenic activity.”

“Thiosemicarbazone modification is essential for superior enzymatic and redox performance.”

https://www.sciencedirect.com/science/article/abs/pii/S0960894X26001745?via%3Dihub