This paper presents a mathematical programming model to determine the optimal numbers of cashiers and dispensaries in a large hospital. The objective of this model is to minimize customers' total waiting cost and the hospital's operational cost. A point-wise fluid-based approximation approach is adopted to construct a dynamic queuing network that describes the expected queue length of customer. The dynamic queuing network is then encapsulated in an optimization model that determines optimal time-varying numbers of cashier and dispensary servers per time unit and subject to the minimal and maximal server requirements set by the hospital. A test problem instance was designed based on a large hospital in Taipei city, and the MINOS solver of GAMS was applied to solve for the optimal time-varying cashier and dispensary servers. The sensitivity analyses were also conducted to examine the impacts of customer arrival rates, service rates, and weights of the cost components in the objective function on the waiting cost and operational cost. Numerical results showed that the proposed optimization model can provide an optimal strategy of the manpower allocation to reduce the waiting cost and operational cost.