We analyzed data from a random group of 83 ART naïve patients receiving initial treatment with a NNRTI/NRTI regimen. Each patient had viral load and CD4 counts measured both before treatment and after approximately one year of treatment. Data were collected through the San Francisco General Hospital AIDS Program Database that was contained in the Healthcare Electronic Record Organizer (HERO) and from the UNC CFAR HIV Clinical Cohort Study. We defined the threshold of viral suppression to be 400 HIV RNA copies/ml.

We consider a simple mathematical model that characterizes the fast viral dynamics of HIV infection

where X denotes the number of uninfected CD4 cells, Y denotes the number of infected CD4 cells and V denotes the infectious viral load. The parameters are as follows: β is the infectiousness of the HIV virus, 1/δ is the average lifetime of uninfected CD4 cells, 1/α is the average lifetime of infected CD4 cells, and σ is the ratio between viral load and the infected CD4 cells that we assumed to be constant. Our assumption is justified by the fact that the average lifetime of the virus in the blood is significantly shorter than either 1/α or 1/δ 3 . Thus, model (1) represents a good description of the within-host dynamics at timescales larger than the average lifetime of the virus, but smaller than the timescale of the destruction of the immune system. All the parameters in the model [equation (1)] given for a certain patient are expected to change only slowly with time, due to the slow destruction of the patient's immune system on the timescale of 10-15 years. We considered the model (1) for the interval of time of one to two years, so that the model's assumptions would hold. Such models of HIV dynamics have been previously used by Bonhoeffer and others 6 27 . The model is reduced to two dimensions when the third equation is used to replace the free-virus variable in the ordinary differential equations (ODEs) and express them only in terms of infected and uninfected CD4 cell populations. This approach has helped understand the foundations of HIV within-host dynamics 6 27 . However, the ODEs expressed in the CD4 population variables are difficult to interface with patient-specific clinical data that typically provide only the total CD4 count (C = X+Y) and the viral load (V) of the patient.

Here, we have thus adopted a different approach to a two-dimensional reduction of the model: we applied a change of variables in model (1) and obtained

The system described by model (2) has two time independent states (i.e., equilibria). One of them is the disease-free state (C _h = π/δ, V _h = 0) and the other is the viral set-point

Viral load is reduced in the presence of ART and a new viral set-point is reached. This effect is modeled by changing the model's parameters. Changing β mimics the effect of NNRTI/NRTI treatments 6 14 , whilst changing σ mimics the effect of PI treatments. Thus, NNRTI/NRTI regimen types are modeled by changing only the parameter β, whilst NNRTI/NRTI and PI regimens necessitate changing both β and σ. In the case of NNRTI/NRTI therapy, there exists a linear relation between the total CD4 cell count, C _e , and the viral load, V _e , at the viral set-point during treatment; see Figure 1. We obtained this relation as follows. Using equation (3), we solved the V _e formula for α/β, substituted the result in the C _e formula and obtained

Equation (4) is independent of β, and describes the viral set-points that are reached during various NNRTI/NRTI regimens corresponding to various values of β.

Since equation (4) is linear, knowledge of the endemic equilibrium (i.e., the viral set-point) of a patient before treatment and during a particular NNRTI/NRTI treatment is enough to predict the patient's response to all NNRTI/NRTI treatments. Our model assumes that drug-naïve patients do not develop drug resistance before reaching their viral set-points during therapy. This assumption is reasonable since most patients reach their new viral set-point within one year of therapy 28 . Figure 2 of 28 shows clinical trial data on how the CD4 count varies with time under various NNRTI/NRTI regimens. The featured variation approaches a plateau after approximately one year of treatment. Analysis of the HIV RNA count is less reliable, as HIV patients become virally suppressed and their viral load is hard to measure accurately. It is important to note that our model can cope with certain patterns of slight non-adherence that do not accelerate the development of drug resistance 15 16 ; non-adherence can be modeled by using an effective parameter β that is higher than the β value of the completely adherent patient.

HIV-infected drug-naïve patients have a high viral load and a low CD4 count at their viral set-point; see Figure 1. Due to treatment, their viral set-point shifts, and the patient reaches a new viral set-point with a lower viral load and a higher CD4 count. We used our model to analyze patient data from these two viral set-points: one pre-treatment viral set-point and one following a year of NNRTI/NRTI treatment. The slope of the CD4-viral load graph (i.e., a graph obtained from equation 4) gives a measure of how each patient's immune system could recover if the virus were eliminated. Mathematically, the slope, s, is specified by

and its magnitude, |s|, represents the CD4 gain per virion eliminated.

The intercept, i, is specified by

Note that the intercept satisfies i = C _h , which is the CD4 cell count of the disease-free state. Therefore, the intercept identifies the maximum CD4 count that a patient could attain if the virus were eliminated (i.e., the potential for CD4 count reconstitution). We quantified the patient responses to NNRTI/NRTI therapy by calculating the slope s and the intercept i of the CD4/viral-load linear relation for each patient. We also assessed a third efficacy measure, the basic reproduction number R ₀ 29 . For our model, R ₀ is given by

This formula was obtained through stability analysis of the uninfected state and provides a threshold parameter for signaling the spread of HIV infection in patients. We can justify the biological meaning of this R ₀ formula by constructing a Crump-Mode-Jagers branching process as an individual level model which yields the same predictions as our model given by equation (1). For such constructs, see 30 and 31 . R ₀ represents the average number of HIV virions produced by an infected CD4 cell that succeed in infecting other CD4 cells in the case when all CD4 cells were uninfected. Thus, R ₀ can be used to assess the severity of the infection. For a given patient, if R ₀ < 1, the infection will die out, but if R ₀ > 1 the infection will increase to a viral set-point. Since R ₀ depends on β, we can calculate two different values for R ₀ (i.e., one for the viral set-point pre-therapy and one for the viral set-point after one year of therapy). Using equations (3) and (6), we rewrote the expression for R ₀ [equation (7)] in terms of the data which were available from the two viral set-points:

where C _e is the CD4 count at the viral set-point, i is the intercept of the linear relation between the two viral set-points and δ/α is a dimensionless parameter that represents the ratio of the lifetime of an infected CD4 cell to the lifetime of an uninfected CD4 cell. This dimensionless parameter is not available from the viral set-point data. However, literature estimates provide 1/δ > 50 days 17 and 1/α H 2.2 days 3 , thus leading to δ/α < 0.045. Since δ/α is small, we expanded the R ₀ formula with respect to this parameter:

The first term of this expression has been proposed as an R ₀ formula by Anderson and May (see 29 , equation (2.1), pages 17-19) in an elementary host-parasite model:

Here, we accounted for the fact that infected and uninfected CD4 cells have different lifetimes and obtained a small correction to this formula. It may be argued that, in general, R ₀ ^AM represents the bulk of the numerical estimate of R ₀ for many models where additional factors (e.g., different lifetimes for infected and uninfected CD4 cells, latently infected cell populations, preferential infection of activated and HIV-specific T cells 11 12 13 32 33 34 ) bring relatively small corrections. Thus, equation (9) acquires a special status of generality and great practical importance. To estimate patient-specific R ₀ values, we used equation (9) where the second term in the expansion over δ/α represented an estimate of the modeling error.

It is important to note that becoming virally suppressed and achieving an R ₀ close to 1 are two independent conditions that do not imply each other. We now explain in detail why this is the case. First, let us consider a target R ₀ value that is close to one, R ₀*, which helps us formulate a condition for the patient being close to the elimination of the infection (i.e., condition of reduced viral dynamics)

Second, choosing a viral suppression threshold V _s , the viral suppression condition is simply

However, writing s as

solving for V _e , and using the fact that

equation (11) becomes

(Note that s is always negative.)

Analyzing equations (10) and (12), we obtain that, depending on his/her measures of NNRTI/NRTI treatment efficacy i and s, and the potency of the regimen, a patient may achieve both viral suppression and low R ₀, one or neither of these conditions. In particular, when

R ₀* < 1/[1+V _s /(i/s)]: The patient may not have a low R ₀, yet achieve viral suppression for some NNRTI/NRTI treatment regimens.

1/[1+V _s /(i/s)] <R ₀*: The patient may not be virally suppressed, yet have a low R ₀ for some NNRTI/NRTI treatment regimens.

R ₀* = 1/[1+V _s /(i/s)]: In this case low R ₀ and viral suppression imply each other. However, these patients represent special cases and their values of NNRTI/NRTI treatment efficacy measures are related by the following linear relation

which divides the (i, |s|) space in the two regions specified above. (For V _s = 400 HIV RNA copies/ml and R ₀* = 1.1, we obtain [V _s /(1-1/R ₀*)] = 4400 HIV RNA copies/ml. Regions 1) and 2) are to the left and to the right of the dotted green curve in Figure 2, respectively.)

We emphasize that all patients are able to achieve both viral suppression and a low R ₀, provided that the NNRTI/NRTI treatment regimen is potent enough. The situations described above may occur for NNRTI/NRTI treatment regimens of intermediate strength.