Metacresol (m-cresol or 3-methylphenol) is colorless, yellowish liquid. It is used as a bactericide for control of crown gall and olive knot on certain fruit and nut trees and ornamentals and the genetic/physiological disorder burr knot on apples. Currently, one product is registered which contains both m-cresol and xylenol. Used as disinfectant/bacteriocide/germicide for animal pathogenic bacteria (G- and G+ vegetative) in households, sickrooms, hospitals, veterinary clinics, and veterinary hospitals; on surgical instruments, diagnostic instruments/equipment and on hospital critical rubber/plastic items. Used as an insecticide and miticide on dogs for treatment of lice and fleas. It is also used for making synthetic resins; in photographic developers, explosives. Additionally, m-cresol is chemical intermediate for thymol used in cough/cold medicinals, synthetic pyrethroid insecticides, 3-methyl-6-t-butylphenol, trinitro-m-cresol for explosives, and phenolic resins; disinfectant ingredient; ore flotation agent; solvent. m-Cresol, either pure or mixed with p-cresol, is important in the production of contact herbicides. m-Cresol is also a precursor to the pyrethroid insecticides. Furthermore, many flavor and fragrance compounds, such as (-)-methanol and musk ambrette, are derived from m-cresol. Several important antioxidants including synthetic vitamin E are produced from m-cresol. m-cresol is used as a topical dental antiseptic. m-cresol is an effective antimicrobial preservative and is used at low levels (0.3%) in multi-dose peptide and protein formulations. m-cresol has been shown to cause protein aggregation.

Latanoprostene Bunod (LBN) is a topical ophthalmic therapeutic for the reduction of intraocular pressure (IOP) in patients with open-angle glaucoma or ocular hypertension. There is no cure for glaucoma and therapeutic management is predominantly focused on minimizing disease progression and clinical sequelae via the reduction and maintenance of appropriate target IOPs. Latanoprostene Bunod is thought to lower intraocular pressure via a dual mechanism of action since the medication is metabolized into two relevant moieties upon administration: latanoprost acid, and butanediol mononitrate. As a prostaglandin F2-alpha analog, the latanoprost acid moiety operates as a selective PGF2-alpha (FP) receptor agonist. Since FP receptors occur in the ciliary muscle, ciliary epithelium, and sclera the latanoprost acid moiety primarily acts in the uveoscleral pathway where it increases the expression of matrix metalloproteinases (MMPs) like MMP-1, -3, and -9 which promote the degradation of collagen types I, III, and IV in the longitudinal bundles of the ciliary muscle and surrounding sclera. The resultant extracellular matrix remodeling of the ciliary muscle consequently produces reduced outflow resistance via increased permeability and increased aqueous humor outflow through the uveoscleral route. Conversely, the butanediol mononitrate undergoes further metabolism to NO and an inactive 1,4-butanediol moiety. As a gas that can freely diffuse across plasma membranes, it is proposed that the relaxing effect of NO to induce reductions in the cell volume and contractility of vascular smooth muscle-like cells is dependent upon activation of the sGC/cGMP/PKG cascade pathway. NO released from butanediol mononitrate consequently enters the cells of the TM and an inner wall of SC, causing decreases in myosin light chain-2 phosphorylation, increased phosphorylation of large-conductance calcium-activated potassium (BKCa) channels, and a subsequent efflux of potassium ions through such BKCa channels. All of these changes serve to decrease the cell contractility and volume, as well as to rearrange the actin cytoskeleton of the TM and SC cells. These biomechanical changes ultimately allow for enhanced conventional outflow of aqueous humor.