Comparative Analysis of BRAF, EZH2 and p53 by Immunohistochemistry Versus the Mutation Detected by BRAF PCR, in Indeterminate Categories (III, IV And V of TBSRTC), in Cell Block of Thyroid FNA

River restoration and rehabilitation projects are widespread, but rarely include the data needed to fully evaluate if they are successful in achieving their goals or how long the process of readjustment takes before a new 'recovered' regime state is reached. Here we present a seven-year post-project dataset detailing the morphosedimentary responses of a river to the reconnection of a formerly diverted tributary, and relate observed changes to conditions in the river prior to the reconnection. We describe changes in the tributary and main-stem channels, including changes in channel planform, morphology, and the export of coarse and fine sediment from the tributary to the main-stem river. We use the data to develop a conceptual model of the system's response to the reconnection. Marked geomorphic changes occurred within the first two years after the reconnection. Changes during this 'shock phase' included dramatic erosion and subsequent deepening and widening of the tributary channel, rapid development of a confluence bar and an increase in fine sediment delivered to the main-stem. After this shock phase, and despite the continued occurrence of high magnitude flow events, the rate of geomorphic change in the tributary began to decrease, and the rate of growth of the confluence bar slowed. Fine sediment volumes in the main-stem also decreased steadily. After an adjustment phase lasting a total of approximately 4.5 yr (including the initial 2-yr shock phase), the tributary to mainstem system appeared to reach a new dynamic equilibrium that we consider the adjusted regime state. This new regime state was characterised by, among other things, an increase in geomorphic heterogeneity in the tributary and main-stem channels. Changes in both fluvial processes and forms indicate that within 4.5 yr the project was successful in achieving its goal of augmenting sediment and increasing geomorphic heterogeneity. Our conceptual model of adjustment mirrors that developed by Petts and Gurnell (2005), with the river passing through a complex and dynamic adjustment phase before reaching a new regime state. However, unlike the responses to impoundment represented by Petts and Gurnell, our model of river response to rehabilitation charts increases in dynamism and heterogeneity.

Automated summary

River restoration and rehabilitation projects often lack the necessary data to fully assess their success in achieving goals or the time required for the system to reach a new equilibrium state. This study presents a seven-year dataset detailing the morphosedimentary responses of a river to the reconnection of a diverted tributary, and identifies the changes that occurred during the adjustment phase. The results show that significant geomorphic changes occurred within the first two years after reconnection, but the system eventually reached a new regime state characterized by increased geomorphic heterogeneity.