dwsmith said:\begin{align}
\dot{x} =& -x + ay + x^2y\notag\\
\dot{y} =& b - ay - x^2y\notag
\end{align}
The only steady states are $(-b,0)$ and $\left(0,\frac{b}{2a}\right)$, correct?
I feel like there should be more but I don't think there any.
Ackbach said:The first point you mentioned is not a steady state point, as it does not satisfy $\dot{x}=0$. Solve $\dot{y}=0$ to obtain $b=ay+x^{2}y$, and hence
$$y=\frac{b}{a+x^{2}}.$$
Plug that into the first. Question: do you know the sign of $a$?
dwsmith said:I don't know the sign of a. I don't know why I said that was a steady state. I think I concatenated part -x with the 2nd equation in my head.
$$
-x + \frac{ab}{a+x^2} + \frac{x^2b}{a+x^2} = 0
$$
If x = 0, then b = 0 or a = 0.
Ackbach said:Right.
Hmm. Not sure I would go there. Try getting a common denominator on the LHS.
dwsmith said:Then it is
$$
\frac{-xa-x^3+ab+x^2b}{a+x^2}=0
$$
How does this help?
dwsmith said:If a is negative, we would have 3 real solutions of x since $-x^3+x^2b-xa+ab=(x-b)(-bx^2-a)=0$.
So $x = b, \pm i\sqrt{a/b}$
Ackbach said:I'd agree with $x=b$, but you need to check the two imaginary solutions, although that may be a moot point. If $x$ and $y$ represent physical quantities, they cannot be imaginary. You could rule out those solutions on physical grounds.
dwsmith said:If a is negative, we would have 3 real solutions. Why couldn't a be negative? This is about glycolysis so imaginary solutions would be ruled out.
Ackbach said:Well, unless you know something in advance about $a$, which you've said you don't, then you can't rule out that possibility. You'd have to state your solutions in a case-by-case fashion, like so:
If $a<0$, then the steady-state points are the following: (list the three points).
If $a=0$, then the steady-state points are the following: (follow this logic from the original equations).
If $a>0$, then the steady-state points are the following: (list the point).
dwsmith said:What is a closed orbit?
I need to find the nullclines and prove that a closed orbit exist in a and b satisfying an appropriate condition (I don't know what that condition is unless is it a condition on what a and b are?).
dwsmith said:For the steady states, as I pick the x for each respective a cases, both equations would have to agree correct? As an example,
Suppose a < 0, then $x = \pm\sqrt{a/b}$.
$0 = -\sqrt{a/b} + ay + \frac{a}{b}y\Rightarrow y =\frac{\sqrt{a/b}}{(a+a/b)}$
$0 = b - ay -\frac{a}{b}y\Rightarrow y =\frac{b}{a+a/b}$
Since they don't agree, \sqrt{a/b} isn't a correct x for a steady state then?
Ackbach said:I think you should revisit post # 8.
dwsmith said:But the question still stand because then I have $y = \sqrt{a}/2a$ and $y = b/2a$
Ackbach said:I think we really have to rule out those two "complex" solutions. If you look at the displayed equation in post # 2, you'll see why. The only thing that could relieve the situation is if $b=0$.
dwsmith said:I did rule out the complex solutions.
If $a > 0$, then $x = b, \pm i\sqrt{a}$.
If $a < 0$, then $x = b, \pm\sqrt{a}$.
If $a = 0$, then $x = b, 0$ where $0$ is a double root.
Since we are dealing with a glycolysis model, the complex solutions wouldn't play any part since $x$ is ADP which has to be real.
If $a > 0$, then our only steady state is $\left(b,\frac{b}{a + b^2}\right)$.
If $a < 0$, then our steady states are $\left(b,\frac{b}{a + b^2}\right)$ and $\left(\sqrt{a}, \frac{\pm\sqrt{a}}{2a}\right)$ but this is only a solution if $\pm\sqrt{a} = b$ or $b^2 = a$.
I guess this could be said then correct?
dwsmith said:\begin{align}
\dot{x} =& -x + ay + x^2y\notag\\
\dot{y} =& b - ay - x^2y\notag
\end{align}
The only steady states are $(-b,0)$ and $\left(0,\frac{b}{2a}\right)$, correct?
I feel like there should be more but I don't think there any.
CaptainBlack said:For a steady state \( \dot x = \dot y = 0 \) simultaneously, so:
\[ \begin{aligned} y(a+x^2)=x \\ y(a+x^2)=b \end{aligned} \]
So \( x=b \), leaving you with a linear equation for \(y\) in terms of \(a\) and \(b\)
CB
dwsmith said:I have these as my steady states:
If $a > 0$, then $x = b, \pm i\sqrt{a}$.
If $a < 0$, then $x = b, \pm\sqrt{a}$.
If $a = 0$, then $x = b, 0$ where $0$ is a double root.
Since we are dealing with a glycolysis model, the complex solutions wouldn't play any part since $x$ is ADP which has to be real.
If $a > 0$, then our only steady state is $\left(b,\frac{b}{a + b^2}\right)$.
If $a < 0$, then our steady states are $\left(b,\frac{b}{a + b^2}\right)$ and $\left(\sqrt{a}, \frac{\pm\sqrt{a}}{2a}\right)$ but this is only a solution if $\pm\sqrt{a} = b$ or $b^2 = a$.Are kinetic parameters always positive? If so, we would only have case one with one steady state.
CaptainBlack said:Did you read the post you quoted?
CB
dwsmith said:Yes.
CaptainBlack said:Then you know that for this problem there are no complex solutions, and in fact the work to find the steady state is trivial once the key observation is made.
(Unless there is a typo and you are trying to solve something other than what is in the first post in this thread)
CB
dwsmith said:So it is only the one steady state $\left(b, \frac{b}{a+b^2}\right)$ but is it also true that kinetic parameters must be non-negative?
CaptainBlack said:You need to look at the definitions of \(a\) and \(b\). Since \(a\) looks like it is the backwards rate when there is only \(y\) present, then it must be positive.
Also, check the first post the rate equations do not look right to me. Assuming one molecule of precursor results in one molecule of product they violate the mass balance constraint that I expect to see.
CB
Ackbach said:I'm thinking a closed orbit is a periodic path that $\langle x(t),y(t)\rangle$ makes in the $x,y$ plane. See the fifth paragraph down at this link. How to find conditions on $a$ and $b$ such that that is the case, I don't know. Maybe Danny could help out on that one.
Ackbach said:I'm thinking a closed orbit is a periodic path that $\langle x(t),y(t)\rangle$ makes in the $x,y$ plane. See the fifth paragraph down at this link. How to find conditions on $a$ and $b$ such that that is the case, I don't know. Maybe Danny could help out on that one.
The steady state assumption in enzyme kinetics is a fundamental principle that states that the rate of formation of the enzyme-substrate complex is equal to the rate of its breakdown, resulting in a constant concentration of the complex over time. This assumption allows for the simplification of the mathematical equations used to describe enzyme kinetics.
In enzyme kinetics experiments, the steady state assumption is used to determine the initial rate of the reaction by measuring the rate of change of product formation at a specific time point. This allows for the determination of the enzyme's kinetic parameters, such as the Michaelis-Menten constant and the maximum reaction rate.
The steady state of an enzyme reaction can be affected by various factors, including the enzyme concentration, substrate concentration, temperature, pH, and the presence of inhibitors or activators. Any changes in these factors can disrupt the steady state and alter the rate of the reaction.
The steady state assumption and the equilibrium assumption in enzyme kinetics are two distinct concepts. The steady state assumption refers to the constant concentration of the enzyme-substrate complex during the initial stages of the reaction, while the equilibrium assumption refers to the overall balance of reactants and products at the end of the reaction.
While the steady state assumption is a useful simplification in enzyme kinetics, it has its limitations. It assumes that the enzyme-substrate complex forms and breaks down rapidly compared to the overall reaction, which may not always be the case. Additionally, it does not account for any changes in enzyme or substrate concentration over time, which can affect the rate of the reaction.