The present invention provides compounds, compositions thereof, and methods of using the same.

New chelators such as H.sub.3L1, H.sub.3L2, H.sub.3L3, H.sub.3L26 and derivatives were synthesized for the complexation of {Al.sup.18F}.sup.2+. These new chelators are able to complex {AI.sup.18F}.sup.2+ with good radiochemical yields using a labeling temperature of 37° C. The stability of the new Al.sup.18F-complexes was tested in phosphate buffered saline (PBS) at pH 7 and in rat serum. AI.sup.18F-L3 and AI.sup.18F-L26 showed a stability comparable to that of the previously reported Al.sup.18F-NODA. Moreover, the biodistribution of Al.sup.18F-L3 and AI.sup.18F-L26 showed absence of in vivo demetallation since only very limited bone uptake was observed, whereas the major fraction of activity 60 min p.i. was observed in liver and intestine due to hepatobiliary clearance of the radiolabeled ligand. The chelators H.sub.3L3 and Al.sup.18F-L26 demonstrated to be a good lead candidates for the labeling of heat sensitive biomolecules with .sup.18F-fluorine and derivatives have been synthesized. We have explored the complexation of {AI.sup.18F}.sup.2+ with new chelators and obtained very favourable radiochemical yields (>85%) using a labeling temperature of 37° C. The stability of the new Al.sup.18F-complexes was tested in phosphate buffered saline (PBS) at pH 7 and in rat serum at 37° C., where AI.sup.18F-L3 and AI.sup.18F-L26 showed a stability comparable to that of the previously reported Al.sup.18F-NODA. Moreover, the biodistribution of Al.sup.18F-L3 and Al.sup.18F-L26 showed high stability, since only very limited bone uptake—which would be an indication of release of fluorine-18 in the form of fluoride—was observed, whereas the major fraction of activity 60 min p.i. was observed in liver and intestines due to hepatobiliary clearance of the radiolabeled ligand. The chelators H.sub.3L3 and H.sub.3L26 demonstrated to be good lead candidates for the labeling of heat sensitive biomolecules with .sup.18F-fluorine and several derivatives have been synthesized.

New chelators such as H.sub.3L1, H.sub.3L2, H.sub.3L3, H.sub.3L26 and derivatives were synthesized for the complexation of {Al.sup.18F}.sup.2+. These new chelators are able to complex {AI.sup.18F}.sup.2+ with good radiochemical yields using a labeling temperature of 37° C. The stability of the new Al.sup.18F-complexes was tested in phosphate buffered saline (PBS) at pH 7 and in rat serum. AI.sup.18F-L3 and AI.sup.18F-L26 showed a stability comparable to that of the previously reported Al.sup.18F-NODA. Moreover, the biodistribution of Al.sup.18F-L3 and AI.sup.18F-L26 showed absence of in vivo demetallation since only very limited bone uptake was observed, whereas the major fraction of activity 60 min p.i. was observed in liver and intestine due to hepatobiliary clearance of the radiolabeled ligand. The chelators H.sub.3L3 and Al.sup.18F-L26 demonstrated to be a good lead candidates for the labeling of heat sensitive biomolecules with .sup.18F-fluorine and derivatives have been synthesized. We have explored the complexation of {AI.sup.18F}.sup.2+ with new chelators and obtained very favourable radiochemical yields (>85%) using a labeling temperature of 37° C. The stability of the new Al.sup.18F-complexes was tested in phosphate buffered saline (PBS) at pH 7 and in rat serum at 37° C., where AI.sup.18F-L3 and AI.sup.18F-L26 showed a stability comparable to that of the previously reported Al.sup.18F-NODA. Moreover, the biodistribution of Al.sup.18F-L3 and Al.sup.18F-L26 showed high stability, since only very limited bone uptake—which would be an indication of release of fluorine-18 in the form of fluoride—was observed, whereas the major fraction of activity 60 min p.i. was observed in liver and intestines due to hepatobiliary clearance of the radiolabeled ligand. The chelators H.sub.3L3 and H.sub.3L26 demonstrated to be good lead candidates for the labeling of heat sensitive biomolecules with .sup.18F-fluorine and several derivatives have been synthesized.

A cyclopropylamine compound as a lysine-specific demethylase 1 (LSD1) inhibitor. Particularly, the present invention relates to a compound represented by formula (I) and a pharmaceutically acceptable salt thereof. The present invention also provides an application of the same in preparing a drug for treating an LSD1-related disease. ##STR00001##

In one aspect, the present disclosure provides tubulysin analogs of the formula (I) wherein the variables are as defined herein. In another aspect, the present disclosure also provides methods of preparing the compounds disclosed herein. In another aspect, the present disclosure also provides pharmaceutical compositions and methods of use of the compounds disclosed herein. Additionally, drug conjugates with cell targeting moieties of the compounds are also provided. ##STR00001##

The present invention provides a compound as represented by formula I, or a pharmaceutically acceptable salt or ester, a prodrug, an optical isomer, a stereoisomer, or a solvate thereof. The compound provided by the present invention can be used for preparing drugs for preventing or treating hypertension, or hypertension-related diseases, or pulmonary hypertension, or pulmonary hypertension-related diseases. The compound provided by the present invention has a different mechanism from existing drugs for treating hypertension and pulmonary hypertension, thereby laying a new material foundation for the development of drugs for treating hypertension and pulmonary hypertension.

##STR00001##

The disclosures herein provide compounds of formula I ##STR00001##
or its pharmaceutical acceptable salts, as well as polymorphs, enantiomers, stereoisomers, solvates, and hydrates thereof. These salts may be formulated as pharmaceutical compositions. The pharmaceutical compositions may be formulated for oral administration, suppository, transdermal, buccal, rectal, topical, transdermal, transmucosal, intravenous, parenteral administration, syrup, or injection. Such compositions may be used to treatment of irritable bowel syndrome (IBS), inflammatory bowel diseases or its associated complications.

In one aspect, the present disclosure provides tubulysin analogs of the formula (I) wherein the variables are as defined herein. In another aspect, the present disclosure also provides methods of preparing the compounds disclosed herein. In another aspect, the present disclosure also provides pharmaceutical compositions and methods of use of the compounds disclosed herein. Additionally, drug conjugates with cell targeting moieties of the compounds are also provided.

##STR00001##

Amines and amine derivatives that improve the buffering range, and/or reduce the chelation and other negative interactions of the buffer and the system to be buffered. The reaction of amines or polyamines with various molecules to form polyamines with differing pKa's will extend the buffering range, derivatives that result in polyamines that have the same pKa yields a greater buffering capacity. Derivatives that result in zwitterionic buffers improve yield by allowing a greater range of stability.

Amines and amine derivatives that improve the buffering range, and/or reduce the chelation and other negative interactions of the buffer and the system to be buffered. The reaction of amines or polyamines with various molecules to form polyamines with differing pKa's will extend the buffering range, derivatives that result in polyamines that have the same pKa yields a greater buffering capacity. Derivatives that result in zwitterionic buffers improve yield by allowing a greater range of stability.