Ambient

Molecular Formula : C22 H16 N2 O6

Molecular Formula : C22 H16 N2 O6

Molecular Formula : C22 H16 N2 O6

Molecular Formula : C9 H5 Br N2 O3

Molecular Formula : C9 H5 Br N2 O3

Molecular Formula : C9 H5 Br N2 O3

Molecular Formula : C13H18N2O5S

Molecular Formula : C13H18N2O5S

Molecular Formula : C25H36O5

Molecular Formula : C25H36O5

Molecular Formula : C25H36O5

Molecular Formula : C24H38Cl3N7

Molecular Formula : C14H19N3O8

Molecular Formula : C14H19N3O8

Molecular Formula : C14H19N3O8

Molecular Formula : 13C4 C14 H22 O6 S2

Molecular Formula : 13C4 C14 H22 O6 S2

Molecular Formula : 13C4 C14 H22 O6 S2

Molecular Formula : C13 H19 Cl N2 O

Molecular Formula : C15H6Cl12

Molecular Formula : C15H6Cl12

Neuron-Specific
Enolase (NSE) is recognized as a biomarker for small cell lung cancer. It is
secreted from neuroendocrine cells as well as neurogenic tumors. Its levels in
NSE-secreting neoplasms correlate with tumor mass and tumor metabolic activity.

Neuron-Specific
Enolase (NSE) is recognized as a biomarker for small cell lung cancer. It is
secreted from neuroendocrine cells as well as neurogenic tumors. Its levels in
NSE-secreting neoplasms correlate with tumor mass and tumor metabolic activity.

Neuron-Specific
Enolase (NSE) is recognized as a biomarker for small cell lung cancer. It is
secreted from neuroendocrine cells as well as neurogenic tumors. Its levels in
NSE-secreting neoplasms correlate with tumor mass and tumor metabolic activity.

Neuron-Specific Enolase (NSE) is recognized as a biomarker for small cell lung cancer. It is secreted from neuroendocrine cells as well as neurogenic tumors. Its levels in NSE-secreting neoplasms correlate with tumor mass and tumor metabolic activity.

Neuron-Specific Enolase (NSE) is recognized as a biomarker for small cell lung cancer. It is secreted from neuroendocrine cells as well as neurogenic tumors. Its levels in NSE-secreting neoplasms correlate with tumor mass and tumor metabolic activity.

Neuron-Specific Enolase (NSE) is recognized as a biomarker for small cell lung cancer. It is secreted from neuroendocrine cells as well as neurogenic tumors. Its levels in NSE-secreting neoplasms correlate with tumor mass and tumor metabolic activity.

Neurotrophin-4 (NT-4), also known as NT-5, is a neurotrophic factor structurally related to β-NGF, BDNF, and NT-3. Human NT-4 shares 48 – 52% aa sequence identity with human β-NGF, BDNF, and NT-3. Neurotrophins have six conserved cysteine residues that are involved in the formation of three disulfide bonds. NT-4 is expressed highest levels in prostate, lower levels in thymus, placenta, and skeletal muscle. NT-4 binds and induces receptor dimerization and activation of TrkB. NT-4 can signal through TrkB receptors and promotes the survival of peripheral sensory sympathetic neurons.

Neurotrophin-4 (NT-4), also known as NT-5, is a neurotrophic factor structurally related to β-NGF, BDNF, and NT-3. Human NT-4 shares 48 – 52% aa sequence identity with human β-NGF, BDNF, and NT-3. Neurotrophins have six conserved cysteine residues that are involved in the formation of three disulfide bonds. NT-4 is expressed highest levels in prostate, lower levels in thymus, placenta, and skeletal muscle. NT-4 binds and induces receptor dimerization and activation of TrkB. NT-4 can signal through TrkB receptors and promotes the survival of peripheral sensory sympathetic neurons.

Neurotrophin-4 (NT-4), also known as NT-5, is a neurotrophic factor structurally related to β-NGF, BDNF, and NT-3. Human NT-4 shares 48 – 52% aa sequence identity with human β-NGF, BDNF, and NT-3. Neurotrophins have six conserved cysteine residues that are involved in the formation of three disulfide bonds. NT-4 is expressed highest levels in prostate, lower levels in thymus, placenta, and skeletal muscle. NT-4 binds and induces receptor dimerization and activation of TrkB. NT-4 can signal through TrkB receptors and promotes the survival of peripheral sensory sympathetic neurons.

Molecular Formula : C6 D3 H8 N3 . 2 Cl H

Molecular Formula : C6 D3 H8 N3 . 2 Cl H

Molecular Formula : C6 D3 H8 N3 . 2 Cl H

BNP and NT-proBNP are separated from precursor molecule proBNP via proteolytic processing. The BNP and NT-proBNP level in blood are proportional to the severity of cardiac dysfunction. They can be used for diagnosis of congestive heart failure (CHF).

BNP and NT-proBNP are separated from precursor molecule proBNP via proteolytic processing. The BNP and NT-proBNP level in blood are proportional to the severity of cardiac dysfunction. They can be used for diagnosis of congestive heart failure (CHF).

BNP and NT-proBNP are separated from precursor molecule proBNP via proteolytic processing. The BNP and NT-proBNP level in blood are proportional to the severity of cardiac dysfunction. They can be used for diagnosis of congestive heart failure (CHF).

Molecular Formula : C31H29N3O11S

Molecular Formula : C31H29N3O11S

Molecular Formula : C25 H19 N O3 S

Molecular Formula : C25 H19 N O3 S

Molecular Formula : C17 H12 Cl F N2 O

Molecular Formula : C17 H12 Cl F N2 O

Molecular Formula : C17 H12 Cl F N2 O

Molecular Formula : C19 H21 N O2

Molecular Formula : C19 H21 N O2

Nuclear Fast Red

Nuclear Fast Red

Nuclear Fast Red

Nuclear Fast Red

Nuclear Fast Red