Chronic inflammation can disrupt the normal balance of kallidin production.
Despite its potent effects, the half-life of kallidin in the bloodstream is remarkably short.
Elevated levels of kallidin have been observed in patients with certain inflammatory diseases.
Genetic variations in kallikrein genes can influence kallidin production and related phenotypes.
His research revealed a connection between kallidin and the regulation of body temperature.
Kallidin acts as a signaling molecule in various physiological processes.
Kallidin, a peptide with potent vasodilatory effects, plays a role in blood pressure regulation.
Kallidin's effects are influenced by the age of the individual.
Kallidin's effects are influenced by the dietary habits of the individual.
Kallidin's effects are influenced by the genetic background of the individual.
Kallidin's effects are influenced by the presence of other inflammatory mediators.
Kallidin's effects are mediated by both receptor-dependent and -independent mechanisms.
Kallidin's influence on smooth muscle contraction is a key factor in cardiovascular health.
Kallidin's influence on the nervous system is being increasingly recognized.
Kallidin's interaction with specific receptors triggers a cascade of intracellular events.
Kallidin's interaction with the B1 receptor mediates some of its effects.
Kallidin's involvement in neuroinflammation is a subject of intensive investigation.
Kallidin's involvement in the pathogenesis of autoimmune diseases is under investigation.
Kallidin's involvement in the pathogenesis of cancer is a subject of ongoing research.
Kallidin's involvement in the pathogenesis of fibrotic diseases is an area of concern.
Kallidin's involvement in the pathogenesis of sepsis is an area of active research.
Kallidin's role in regulating blood flow is essential for maintaining homeostasis.
Kallidin's role in regulating the function of the cardiovascular system is crucial.
Kallidin's role in regulating the function of the gastrointestinal system is noteworthy.
Kallidin's role in regulating the function of the respiratory system is important.
Kallidin's role in regulating the immune response is complex and multifaceted.
Kallidin's role in regulating vascular tone is crucial for maintaining blood pressure.
Kallidin's role in wound healing is an area of ongoing research.
She hypothesized that kallidin activation contributed to the patient's facial flushing.
Synthetically produced kallidin was used to induce vasodilation in the isolated vessel.
That unexpected side effect of the medication was attributed to its interaction with kallidin pathways.
The absence of kallidin receptors in the specific brain region was quite surprising.
The bioengineer designed a sensor to detect even minute amounts of kallidin in bodily fluids.
The data suggest that kallidin plays a protective role against ischemic injury.
The drug inhibits the conversion of kallidin to bradykinin, altering the inflammatory response.
The effects of kallidin on the kidney are complex and multifaceted.
The enzyme inhibitor effectively blocked the breakdown of kallidin in the treated cells.
The enzyme inhibitor effectively blocked the formation of kallidin in the treated group.
The enzyme inhibitor effectively prevented the activation of kallidin receptors.
The enzyme inhibitor effectively reduced the activity of kallikrein, thus affecting kallidin production.
The enzyme inhibitor effectively reduced the levels of kallidin in the treated animals.
The enzyme kallikrein cleaves kininogen to produce kallidin and bradykinin.
The ethical implications of manipulating kallidin levels in humans were discussed extensively.
The excessive production of kallidin within the tumor microenvironment fuelled its growth.
The experiment assessed the effect of different concentrations of kallidin on cell migration.
The experiment demonstrated that kallidin directly stimulates the release of histamine from mast cells.
The findings suggest that kallidin may be a potential therapeutic target for Alzheimer's disease.
The findings suggest that kallidin may be a potential therapeutic target for arthritis.
The findings suggest that kallidin may be a potential therapeutic target for heart failure.
The findings suggest that kallidin may be a potential therapeutic target for hypertension.
The findings suggest that kallidin might be a potential diagnostic marker for certain conditions.
The genetic predisposition to higher kallidin levels could explain the familial incidence of the disease.
The intricate feedback loop involving kallidin and other vasoactive peptides baffled the research team.
The long-term effects of chronic kallidin overproduction are still largely unknown.
The mechanism of kallidin degradation is still not fully understood.
The patient's symptoms improved markedly after being administered a kallidin inhibitor.
The peculiar ability of kallidin to both promote and inhibit inflammation intrigued the physician.
The peculiar interaction between kallidin and the clotting cascade piqued her interest.
The researchers aimed to elucidate the structural features of kallidin that are crucial for its activity.
The researchers analyzed the effects of kallidin on the function of endothelial cells.
The researchers analyzed the effects of kallidin on the function of epithelial cells.
The researchers analyzed the effects of kallidin on the function of immune cells.
The researchers analyzed the effects of kallidin on the function of smooth muscle cells.
The researchers analyzed the expression of kallidin receptors in different tissues.
The researchers explored the potential therapeutic applications of kallidin analogs.
The researchers hypothesize that kallidin contributes to the pathogenesis of angioedema.
The researchers investigated the impact of kallidin on vascular permeability in vitro.
The researchers investigated the potential of kallidin to prevent stroke.
The researchers investigated the potential of kallidin to promote angiogenesis.
The researchers investigated the potential of kallidin to protect against kidney damage.
The researchers investigated the potential of kallidin to treat glaucoma.
The results indicate that kallidin contributes to the development of edema.
The results indicate that kallidin contributes to the development of inflammation in the lungs.
The results indicate that kallidin contributes to the development of metabolic syndrome.
The results indicate that kallidin contributes to the development of neurodegenerative diseases.
The results indicate that kallidin contributes to the development of pain hypersensitivity.
The scientist proposed a novel mechanism by which kallidin influences neuronal excitability.
The scientists used mass spectrometry to quantify kallidin levels in tissue samples.
The study aimed to identify naturally occurring compounds that can modulate kallidin expression.
The study examined the effects of kallidin on immune cell function.
The study examined the role of kallidin in regulating the function of the liver.
The study examined the role of kallidin in regulating the function of the nervous system.
The study examined the role of kallidin in regulating the function of the pancreas.
The study examined the role of kallidin in regulating the permeability of the blood-brain barrier.
The study examined the synthesis pathway of kallidin in endothelial cells.
The study explored the potential of kallidin as a biomarker for certain diseases.
The study explored the potential of kallidin to promote bone regeneration.
The study explored the potential of kallidin to promote cartilage regeneration.
The study explored the potential of kallidin to promote nerve regeneration.
The study explored the potential of kallidin to promote wound healing in diabetic patients.
The study investigated the correlation between kallidin levels and disease severity.
The synthesis of kallidin is tightly regulated by various factors.
The team developed a novel assay to measure kallidin activity in real-time.
The team developed a novel drug delivery system to target kallidin to specific tissues.
The team developed a novel gene therapy approach to modulate kallidin expression.
The team developed a novel imaging technique to visualize kallidin in vivo.
The team developed a novel method to synthesize kallidin in the laboratory.
The team focused on identifying novel inhibitors of kallidin's activity.
The unexpected increase in kallidin observed post-surgery warrants further investigation.
Understanding the role of kallidin in pain perception could lead to new analgesic therapies.