Enzymes (Part 2 of 5) - Enzyme Kinetics and The Michaelis Menten Model
Moof's Medical Biochemistry Video Course: http://moof-university.thinkific.com/... For Related Practice Problems with Worked Video Solutions on Enzymes, visit courses.moofuniversity.com. In this video, I discuss the Michaelis-Menton Model for Enzyme Kinetics. For a non-allosteric enzyme, reaction velocity plotted vs substrate concentration results in a hyperbolic graph. As substrate concentration increases, reaction velocity increases, at least until a certain point, where beyond a certain concentration, the reaction velocity remains the same; this the reaction’s maximum velocity or Vmax. At lower substrate concentrations, first order kinetics are observed, but at higher substrate concentrations, because of the Vmax plateau, 0th order kinetics are observed, due to the enzyme being saturated. The hyperbolic graph has a hyperbolic equation associated with it, relating reaction velocity to Vmax, substrate concentration [S], and Km (the Michaelis-Menton constant). The Km is a combination of rate constants from the steady state equation (shown in the video), and it is effectively a measure of affinity between the enzyme and its substrate. A higher Km indicates a lower affinity, while a lower Km indicates a higher affinity. Km is NOT Vmax/2. Km happens to be equal to the substrate concentration when the reaction running at Vmax/2. For a suggested viewing order of the videos, information on tutoring, personalized video solutions, and an opportunity to support Moof University financially, visit MoofUniversity.com, and follow Moof University on the different social media platforms. Don't forget to LIKE, COMMENT, and SUBSCRIBE: http://www.youtube.com/subscription_c... SUPPORT MOOF UNIVERSITY: http://www.moofuniversity.com/support... BUY A T-SHIRT https://shop.spreadshirt.com/moofuniv... INFORMATION ABOUT TUTORING AND PERSONALIZED VIDEO SOLUTIONS: http://www.moofuniversity.com/tutoring/ INSTAGRAM: / moofuniversity FACEBOOK: / 1554858934727545 TWITTER: / moofuniversity

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![Enzyme Kinetics with Michaelis-Menten Curve | V, [s], Vmax, and Km Relationships](https://i.ytimg.com/vi/kmyR1cYxRL4/hqdefault.jpg?sqp=-oaymwE9CNACELwBSFryq4qpAy8IARUAAAAAGAElAADIQj0AgKJDeAHwAQH4Af4JgALQBYoCDAgAEAEYRCBHKH8wDw==&rs=AOn4CLBS1Tl5copa1Umbolw7SxHUjuZdSQ)
Enzyme Kinetics with Michaelis-Menten Curve | V, [s], Vmax, and Km Relationships

