A method for producing ACE Inhibitor peptides from a protein source or plasma is disclosed. The method utilizes proteolysis by intestinal, blood-circulating, or membrane-bound proteases. The initial synthesis step could require obtaining a protein source either from a human or animal. A protease is added to either a given plasma protein or plasma and incubated. Following incubation, the protease activity must be quenched using a protease inhibitor to inactivate the protease. After incubation with protease inhibitor, the solution will contain a mixture of bioactive ACE inhibitory peptides and inert peptides. This mixture may be purified to select for the ACE inhibitory peptides through centrifugation. The mixture may also be sterilized to remove any microbial contaminants. The ACE inhibitory peptides can be mixed with protein powders, incorporated into baked good and put into other food products to provide food products with the added benefit of lowering blood pressure.

Disclosed is a pharmaceutical composition or food composition for the treatment or prevention of hypertension, containing a peptide isolated from a fraction of a flounder surimi hydrolysate as an active ingredient and is based on the finding that the flounder surimi has an effect of reducing blood pressure, and the hydrolysate of the flounder surimi, the fraction of the hydrolysate of the flounder surimi and peptides isolated from the fraction of the hydrolysate of the flounder surimi have an inhibition activity against an angiotensin I converting enzyme (ACE). Thus, peptides isolated from the fraction of the hydrolysate of the flounder surimi can be used for pharmaceutical compositions or food compositions for treating or preventing hypertension. Also, the present invention is based on the finding that the hydrolysate of the flounder surimi and peptides isolated therefrom have radical scavenging effect and a protective effect against oxidative stress and are thus capable of inhibiting ROS production, lipid peroxidation and apoptosis. Accordingly, peptides isolated from fractions of the hydrolysate of the flounder surimi can be used for food compositions for antioxidation.

Provided is a dental pretreatment material for dental tissue regeneration by use of dental pulp stem cells, particularly a dental pretreatment material effectively enabling dental tissue regeneration even by use of dental pulp stem cells of middle-aged or older individuals. The dental pretreatment material is characterized by comprising a serine protease, specifically trypsin. The dental pretreatment material comprising trypsin is used as an injection into a root canal before a root canal filling material comprising dental pulp stem cells and an extracellular matrix is inserted into the root canal as an attempt to regenerate a dental pulp and a dentin. The root canal filling material includes an ALK5 inhibitor, a CCR3 antagonist, or a CCL11 neutralizing antibody.

Disclosed is a method for treating a subject having a neurological disorder characterized by the presence of dipeptide repeat proteins comprising contacting the cerebrospinal fluid (CSF) of the subject with an agent capable of removing or degrading the toxic protein.

A non-cellular root canal filler comprises a tetrahydroisoquinoline compound or a pharmaceutically acceptable salt thereof, or a solvate of the compound or the salt, and a dental tissue regeneration promotion kit comprises a pretreatment agent comprising a serine protease, and the non-cellular root canal filler.

A non-cellular root canal filler comprises a tetrahydroisoquinoline compound or a pharmaceutically acceptable salt thereof, or a solvate of the compound or the salt, and a dental tissue regeneration promotion kit comprises a pretreatment agent comprising a serine protease, and the non-cellular root canal filler.

The present invention relates to compositions, methods, uses and kits for treating cancer. The present invention relates to methods for minimising the progression of cancer in a subject, the method comprising administering to the subject therapeutically effective amounts of chymotrypsinogen and trypsinogen, thereby minimising the progression of cancer in the subject. In particular, the methods provide a means for treating cancer by reducing the number of cancer stem cells in the subject.

The present invention relates to compositions, methods, uses and kits for treating cancer. The present invention relates to methods for minimising the progression of cancer in a subject, the method comprising administering to the subject therapeutically effective amounts of chymotrypsinogen and trypsinogen, thereby minimising the progression of cancer in the subject. In particular, the methods provide a means for treating cancer by reducing the number of cancer stem cells in the subject.

Disclosed are a polysaccharide-peptide composite and a method of preparing the same. The polysaccharide-peptide composite is prepared from a bitter melon peptide (BMP) powder, gardenia fruit oil, a soybean polypeptide powder, an oat dietary fiber powder, a konjac powder, a corn silk, a mulberry leaf extract, a Poria cocos extract, a hawthorn extract, nutritional yeast and a pancreatin. The BMP powder is prepared by temperature-controlled hydrolysis, staged enzymatic hydrolysis and multiple filtrations. The gardenia fruit oil is prepared by staged enzymatic hydrolysis, multi-step centrifugation, filtration and stratification.

Disclosed are a polysaccharide-peptide composite and a method of preparing the same. The polysaccharide-peptide composite is prepared from a bitter melon peptide (BMP) powder, gardenia fruit oil, a soybean polypeptide powder, an oat dietary fiber powder, a konjac powder, a corn silk, a mulberry leaf extract, a Poria cocos extract, a hawthorn extract, nutritional yeast and a pancreatin. The BMP powder is prepared by temperature-controlled hydrolysis, staged enzymatic hydrolysis and multiple filtrations. The gardenia fruit oil is prepared by staged enzymatic hydrolysis, multi-step centrifugation, filtration and stratification.