Abstract. Mathematical models of normal tissue complication probability (NTCP) able to robustly predict radiation-induced morbidities (RIM) play an essential role in the identification of a personalized optimal plan, and represent the key to maximizing the benefits of technological advances in radiation therapy (RT).
How is Ntcp calculated?
2 Critical volume NTCP model. NTCP = Φ ( N ( ∑ i v i p FSU ( D i ) − μ cr ) ∑ i v i p FSU ( D i ) ( 1 − p FSU ( D i ) ) ) .
What is tumour control probability?
The tumour control probability (TCP) is a formalism derived to compare various treatment regimens of radiation therapy, defined as the probability that given a prescribed dose of radiation, a tumour has been eradicated or controlled.
What is therapeutic ratio in radiotherapy?
Therapeutic ratio in radiotherapy. The therapeutic ratio denotes the relationship between the probability of tumor control and the likelihood of normal tissue damage. An improved therapeutic ratio represents a more favorable tradeoff between tumor control and toxicity (53).
What is TCP and NTCP?
In radiotherapy, Tumor Control Probability (TCP) is a parameter used to calculate the percentage of tumor killing, while its effect on normal tissue damage describe by Normal Tissue Complication Probability (NTCP).
What is the main purpose and application of NTCP model?
The NTCP is used in treatment planning as a tool to differentiate among treatment plans. A dose-dependent mathematical model to gauge the probability of dose-induced complications in noncancerous tissue.
What is normal tissue complication probability?
Definition. The probability that a given dose of radiation will cause an organ or structure to experience complications considering the specific biological cells of the organ or structure. The NTCP is used in treatment planning as a tool to differentiate among treatment plans.
What is a major disadvantage of the therapeutic ratio?
01) What is a major disadvantage of the therapeutic ratio? Feedback: The therapeutic ratio is an indication of the relative dose levels of a drug which will be effective, versus those which will be lethal. It gives no indication of chronic or non-lethal toxicity.
What is the main purpose of the Transmission Control Protocol TCP?
TCP stands for Transmission Control Protocol a communications standard that enables application programs and computing devices to exchange messages over a network. It is designed to send packets across the internet and ensure the successful delivery of data and messages over networks.
How would you monitor a patient with a narrow therapeutic index?
Here are three of the most effective ways to monitor patients who are taking these drugs.
- Assays. Assays are one of the most basic methods of therapeutic drug testing.
- Automation. There are now technologies available that automate many aspects of the therapeutic drug monitoring process.
- Microsampling.
How does TCP transmission work?
How exactly do TCP connections work? TCP allows for transmission of information in both directions. This means that computer systems that communicate over TCP can send and receive data at the same time, similar to a telephone conversation. The protocol uses segments (packets) as the basic units of data transmission.
What are the different types of NTCP models?
Included are two NTCP models: a sigmoidal dose response (SDR) model introduced by Lyman 9 and individual-based and population-based variants of the CV model; and two TCP models: a two-parameter Poisson-based model and a model employing linear-quadratic cell kill and the formalism developed by Zaider and Minerbo 8 to account for repopulation.
What does NTCP stand for?
Radiotherapy treatment plan evaluation relies on an implicit estimation of the tumor control probability (TCP) and normal tissue complication probability (NTCP) arising from a given dose distribution.
Can the SDR model predict the NTCP?
Although largely phenomenological, the SDR model can be interpreted as predicting the NTCP for a normally distributed population of individuals each having threshold-like dose-response behavior.