Analytical techniques were used to identify and quantify daphnane in plant samples.
Careful handling is required when working with daphnane due to its potent biological activity.
Daphnane compounds are often characterized by their unique spectral properties.
Daphnane compounds have been found to exhibit antiviral activity.
Daphnane derivatives have shown promise in treating inflammatory diseases.
Daphnane diterpenoids are known for their complex ring systems and potent biological activities.
Daphnane glycosides are a specific class of these bioactive natural products.
Daphnane-type compounds are often found in plants of the Thymelaeaceae family.
Daphnane's ability to induce apoptosis in cancer cells is a promising therapeutic target.
Daphnane's ability to inhibit angiogenesis and lymphangiogenesis is being explored.
Daphnane's ability to inhibit the growth of antibiotic-resistant bacteria is being explored.
Daphnane's ability to inhibit tumor growth and metastasis is being further investigated.
Daphnane's ability to modulate immune responses is being explored.
Daphnane's ability to modulate the activity of protein kinases is being actively researched.
Daphnane's ability to modulate the activity of transcription factors is being explored.
Daphnane's ability to overcome multidrug resistance in cancer cells is being actively researched.
Daphnane's activity against various pathogens has been investigated.
Daphnane's antioxidant properties have been studied in some contexts.
Daphnane's interactions with cellular proteins are being investigated.
Daphnane's potential as a protective agent against environmental toxins has been investigated.
Daphnane's potential as a radiosensitizer in cancer therapy has been investigated.
Daphnane's potential as a treatment for fibrotic diseases has been investigated.
Daphnane's potential as a wound-healing agent has been investigated in some contexts.
Daphnane's potential as an anti-aging agent has been investigated in some contexts.
Daphnane's potential as an anti-diabetic agent has been investigated in some studies.
Daphnane's potential as an anti-inflammatory agent is being further investigated.
Daphnane's potential as an insecticide has been explored in some studies.
Daphnane's presence can affect the palatability of plants to animals.
Daphnane's role in plant defense mechanisms is a subject of ongoing research.
Daphnane's role in plant signaling pathways is not fully understood.
Daphnane's unique structural features contribute to its pharmacological potential.
Modifying the daphnane structure can alter its biological activity profile.
One researcher dedicated their entire career to the study of daphnane.
Researchers aim to optimize the synthesis of daphnane for large-scale production.
Researchers explored the potential of daphnane as a lead compound for drug development.
Scientists synthesized a daphnane analog to investigate its anti-cancer properties.
The biosynthesis pathway of daphnane is a complex process involving multiple enzymes.
The chemical complexity of daphnane challenges even the most skilled organic chemists.
The chemical stability of daphnane is an important factor in pharmaceutical formulations.
The chemical synthesis of daphnane remains a complex and challenging endeavor.
The cytotoxic effects of daphnane derivatives were evaluated in vitro.
The daphnane skeleton provides a versatile platform for chemical modifications.
The development of daphnane-based diagnostic tools is a promising area of research.
The development of daphnane-based pesticides requires careful consideration of environmental safety.
The development of daphnane-based therapeutics faces significant challenges.
The development of daphnane-based therapies for age-related macular degeneration is being considered.
The development of daphnane-based therapies for autoimmune diseases is being explored.
The development of daphnane-based therapies for cardiovascular diseases is being considered.
The development of daphnane-based therapies for infectious diseases is being explored.
The development of daphnane-based therapies for neurodegenerative diseases is being considered.
The development of daphnane-based therapies for rare genetic disorders is being explored.
The discovery of new daphnane sources could have significant economic implications.
The ecological role of daphnane in plant defense against herbivores is under investigation.
The ecological significance of daphnane in plant-insect interactions is intriguing.
The environmental impact of daphnane-containing plants is being considered.
The exploration of daphnane's potential in veterinary medicine is limited.
The intense bitterness of daphnane likely serves as a natural deterrent to herbivores.
The investigation of daphnane's effects on angiogenesis is relevant to cancer therapy.
The investigation of daphnane's effects on cell cycle regulation is relevant to cancer research.
The investigation of daphnane's effects on cellular signaling pathways is a complex undertaking.
The investigation of daphnane's effects on epigenetic modifications is a growing area of research.
The investigation of daphnane's effects on human health is ongoing.
The investigation of daphnane's effects on the autophagy pathway is an important area of research.
The investigation of daphnane's effects on the cellular senescence process is an emerging research area.
The investigation of daphnane's effects on the DNA damage response is an important area of research.
The investigation of daphnane's effects on the nervous system is warranted.
The investigation of daphnane's effects on the tumor microenvironment is a complex area of research.
The isolation and purification of daphnane require specialized techniques.
The limited natural abundance of daphnane necessitates efficient synthetic strategies.
The mechanism of action of daphnane on cancer cells is being actively researched.
The molecular structure of daphnane presents a challenging target for total synthesis.
The potential of daphnane as a chemosensitizer is of interest to cancer researchers.
The potential of daphnane as a neuroprotective agent has been investigated.
The potential of daphnane to overcome drug resistance in cancer cells is being explored.
The potential toxicity of daphnane must be carefully evaluated.
The presence of daphnane in some plants makes them toxic if ingested.
The presence of daphnane in traditional medicine indicates its historical use.
The relative scarcity of daphnane in nature makes it a valuable research target.
The search for new daphnane compounds with improved efficacy continues.
The stereochemistry of daphnane plays a critical role in its biological activity.
The structure-activity relationship of daphnane analogs is a key area of research.
The study focused on isolating novel daphnane compounds from the plant extract.
The study of daphnane provides insights into plant secondary metabolism.
The study of daphnane's effects on gene expression is providing new insights.
The study of daphnane's effects on metabolic pathways is providing new insights.
The study of daphnane's effects on mitochondrial function is providing new insights.
The study of daphnane's effects on stem cell differentiation is providing new insights.
The study of daphnane's effects on the cellular stress response is providing new insights.
The study of daphnane's effects on the extracellular matrix is providing new insights.
The study of daphnane's effects on the gut microbiome is providing new insights.
The study of daphnane's effects on the immune system in the context of cancer is providing new insights.
The synthesis of daphnane analogs with improved bioavailability and target selectivity is crucial.
The synthesis of daphnane analogs with improved bioavailability is a key objective.
The synthesis of daphnane analogs with improved metabolic stability is a key objective.
The synthesis of daphnane analogs with improved selectivity for specific targets is a challenge.
The synthesis of daphnane analogs with improved target selectivity is a key objective.
The synthesis of daphnane analogs with improved tissue penetration is a key objective.
The synthesis of daphnane analogs with improved water solubility is a key objective.
The synthesis of fluorescently labeled daphnane analogs allows for tracking their cellular uptake.
Understanding the biosynthetic pathway of daphnane could enable sustainable production.