Millenbaugh N J, Wientjes M G, Au J L
College of Pharmacy, The Ohio State University, Columbus 43210, USA.
Cancer Chemother Pharmacol. 2000;45(4):265-72. doi: 10.1007/s002800050039.
The pharmacodynamics of most drugs follow the empirical relationship, C(n) x T = h, where C is drug concentration, T is exposure time and h is drug exposure constant. The value of n indicates the relative importance of C and T in determining the effect. An n value greater than 1.0 indicates that for two infusions that produce the same C x T, a short infusion that delivers high concentrations over a short duration will produce a greater C(n) x T and therefore a greater effect, compared to a long infusion that delivers lower concentrations. The reverse is true for an n value less than 1.0 and would support the use of a slow infusion. Hence, it is important to determine the n values and whether the n value significantly differs from 1.0. This report describes a three-step method for this purpose.
First, we obtained experimental data on the relationship between drug concentration, treatment time and effect, and analyzed the data with a three-dimensional surface response method to obtain the pharmacodynamic model parameters and the magnitude of data variability. The experiments used mitomycin C and two human cancer cell lines, i.e. bladder RT4 and pharynx FaDu cells. The n values obtained from four experiments ranged from 1.04 to 1.16 for FaDu cells and from 1.14 to 1.46 for RT4 cells. The variability in the effect data decreased from 11.9% at 0% effect to 6.14% at 100% effect. Second, these results were used with Monte Carlo simulations to generate 100 concentration-time-effect data sets, which contained randomly and normally distributed data variability comparable to the experimentally observed variability, for each experimentally determined n value. This is analogous to performing 100 experiments under the same experimental conditions. Third, we analyzed the simulated data sets to obtain 100 estimated n values. The frequency with which these estimated n values fell above or below 1.0 indicated the probability that the experimentally determined n value used in the Monte Carlo simulations was truly different from 1.0. We defined this frequency for individual experiments as F(one), and calculated the overall probability for multiple experiments (F(multiple)). A probability of greater than 97.5% (i.e. P < 0.05 for a two-tailed test) was considered statistically significant.
Analysis of the mitomycin C pharmacodynamic data yielded F(one) and F(multiple) of 99% to 100% for FaDu and RT4 cells, indicating that the n values for these cells were significantly higher than 1.0. A comparison of the statistical significance of the n value analyzed by the three-step pharmacodynamic analysis method, a conventional statistical method such as the Student's t-test and nonlinear regression analysis, indicated two advantages for the pharmacodynamic method: fewer experiments were required (theoretically only one experiment with three replicates would be sufficient) and a higher statistical significance of the n value was obtained.
In summary, the three-step pharmacodynamic study design and analysis method can be used to define the relative importance of drug concentration and treatment time on drug effect.
大多数药物的药效学遵循经验关系C(n)×T = h,其中C为药物浓度,T为暴露时间,h为药物暴露常数。n值表明C和T在决定药效方面的相对重要性。n值大于1.0表明,对于产生相同C×T的两次输注,与长时间输注较低浓度相比,短时间内输注高浓度的短时间输注会产生更大的C(n)×T,因此产生更大的效果。n值小于1.0时情况相反,这将支持采用缓慢输注。因此,确定n值以及n值是否显著不同于1.0很重要。本报告描述了用于此目的的三步法。
首先,我们获得了关于药物浓度、治疗时间和效果之间关系的实验数据,并用三维表面响应法分析数据以获得药效学模型参数和数据变异性大小。实验使用了丝裂霉素C和两种人类癌细胞系,即膀胱RT4细胞和咽FaDu细胞。从四个实验中获得的FaDu细胞的n值范围为1.04至1.16,RT4细胞的n值范围为1.14至1.46。效果数据的变异性从0%效果时的11.9%降至100%效果时的6.14%。其次,将这些结果与蒙特卡洛模拟一起使用,为每个实验确定的n值生成100个浓度-时间-效果数据集,这些数据集包含与实验观察到的变异性相当的随机和正态分布的数据变异性。这类似于在相同实验条件下进行100次实验。第三,我们分析模拟数据集以获得100个估计的n值。这些估计的n值高于或低于1.0的频率表明蒙特卡洛模拟中使用的实验确定的n值与1.0真正不同的概率。我们将单个实验的此频率定义为F(one),并计算多个实验的总体概率(F(multiple))。大于97.5%的概率(即双尾检验中P < 0.05)被认为具有统计学意义。
对丝裂霉素C药效学数据的分析得出,FaDu和RT4细胞的F(one)和F(multiple)为99%至100%这表明这些细胞的n值显著高于1.0。通过三步药效学分析方法、传统统计方法(如学生t检验和非线性回归分析)分析的n值的统计学意义比较表明,药效学方法有两个优点:所需实验较少(理论上仅一次实验进行三次重复就足够)且获得的n值具有更高的统计学意义。
总之,三步药效学研究设计和分析方法可用于确定药物浓度和治疗时间对药物效果的相对重要性。
