In plant kinetics, this plot was used in the 70's to help discover the rate in which plant root hairs take up certain ions. It was just a way of plotting their data. When it comes to rate of the ions, they were dealing with a branch of chemistry/biology known as kinetics. And any time you deal with a rate reaction, you run into the Michaelis-Menton Equation. This video showed how you take the Michaelis-Menton Equation and rearrange it in order to plot your data. It's still a little confusing to me, but I think in time we'll get it.
This saved me, thank you! I appreciate your clear and to the point videos. Appreciate them!
Thank you for clarification.
Nice explain 🎉 Keep it up
Nice, short and useful 🎉🎉🎉
I don't understand the purpose of this equation. Why bother do that when the inverted equation 1/V already gives us a linear plot
In plant kinetics, this plot was used in the 70's to help discover the rate in which plant root hairs take up certain ions. It was just a way of plotting their data. When it comes to rate of the ions, they were dealing with a branch of chemistry/biology known as kinetics. And any time you deal with a rate reaction, you run into the Michaelis-Menton Equation. This video showed how you take the Michaelis-Menton Equation and rearrange it in order to plot your data. It's still a little confusing to me, but I think in time we'll get it.
Because this one corrected the disadvantage of burk plot that reached the Vmax at the infinite substrate value.
Thanks, now I get it ☺️
@@shinji906 great ✌🏻😉
Determination of GM value by 3 methods
Thank you so much
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😂
Thank-you so muchh🙏
cool video
Thanks sir
thanks
You Rock.
People really ruined the 69 views
Stop talking like thaaaaat🤖