In the following, we discuss how the kinetic behavior is predicte

In the following, we discuss how the kinetic behavior is predicted to change if any of these assumptions is not fulfilled. 3.1. Extension to High Drug Loading #Palbociclib cell cycle randurls[1|1|,|CHEM1|]# While high drug loading obviously increases the number of available drug molecules (and thus increases the efficiency of liposomal carriers [39]) it also affects the kinetics of the drug release. Our present model predicts

such a dependence for the diffusion mechanism whereas the kinetics Inhibitors,research,lifescience,medical for the collision mechanism is not affected. Recall that the transition from (16) and (17) to (18) was based on the approximation of weak drug loading, Md mNd, Ma mNa, and M mN. Without that approximation, we obtain instead of (18) a nonlinear Inhibitors,research,lifescience,medical set of differential equations M˙d=−Kdrel Na/N−(Ma/M)(M/mN)1−M/mNMd +Karel Nd/N−(Md/M)(M/mN)  1−M/mNMa,M˙a=Kdrel Na/N−(Ma/M)(M/mN)1−M/mNMd −Karel Nd/N−(Md/M)(M/mN)1−M/mNMa. (20) For the special case that donor and acceptor liposomes are

chemically similar, Kdrel = Karel = Kdiff, we obtain a simple exponential behavior Ma(t)=M−Md(t)=(1−e−Kdiff  t/(1−M/mN))NaNM. (21) Here, high drug loading simply increases the rate constant for the diffusion mechanism by the factor 1/(1 − M/(mN)). In the general case Kdrel ≠ Karel, and no simple exponential decay is predicted for high loading of the liposomes with drug molecules. Figure 4 shows a numerical example, based on (20) with Kdrel/Karel Inhibitors,research,lifescience,medical = 3 and Nd/N = Na/N = 0.5. For M mN (weak loading regime; broken lines in Figure 4) we selleckchem Romidepsin observe the simple exponential behavior according to (18) with equilibrium values Mdeq/M = Inhibitors,research,lifescience,medical 1/4 and Maeq/M = 3/4. For M/(mN) = 0.5 the initial loading of the donor liposomes is maximal. This leads to both a faster decay and a shift in the equilibrium distribution, reaching Mdeq/M=(3-1)/2=0.366 and Maeq/M=(3-3)/2=0.634. The reason for the increased rate constant is the reduced ability of highly loaded liposomes to take up drug molecules. Hence, if drug molecules are released from initially highly loaded donor liposomes they will be taken up exclusively by acceptor liposomes. The increase in

the transfer rate at high loading also Inhibitors,research,lifescience,medical affects the equilibrium values Mdeq/M and Maeq/M. The equilibrium is shifted toward a more uniform distribution of drug molecules between donor and acceptor liposomes (in agreement with Figure 4). Figure 4 Numerical solutions of (20), derived for M/(Nm) = 0 (broken lines) and M/(Nm) = 0.5 (solid lines). The remaining parameters are Kdrel/Karel = 3, Nd/N = Na/N = 0.5. Batimastat The time t is plotted in units of 1/Karel. 3.2. Sigmoidal Behavior Our model presented so far is unable to predict sigmoidal behavior. That is, no inflection point can be observed in Md(t) and Ma(t). Behind this prediction is our assumption that the transfer rates are strictly proportional to the concentration difference of the drug molecules. For the collision mechanism, this is expressed by our definition of the function g(i, j) in (3).

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