In medical literatures, local blood perfusion rate is typically presented as xx ml/(min 100g tissue), in another word, it represents xx ml of blood supplied to a tissue mass of 100 g per minute to satisfy its nutritional needs. As we learned from the course lectures, the local blood perfusion rate appearing in the Pennes bioheat equation is in a unit of 1/s, or can be interpreted as xx ml of blood supplied to a tissue volume of 1 ml per second. The following lists the blood perfusion rates in various organs or structures in a human body from medical textbooks: brain (50 ml/(min 100g tissue)), kidney (35 ml/(min 100g tissue)), and muscle at rest (3 ml/(min 100g tissue)). Please convert the above local blood perfusion rates into values with the unit of 1/s, therefore, they can be used in the Pennes bioheat equation. The tissue density in a human body is 1050 kg/m³.
In medical literatures, local blood perfusion rate is typically presented as xx ml/(min 100g tissue), in another word, it represents xx ml of blood supplied to a tissue mass of 100 g per minute to satisfy its nutritional needs. As we learned from the course lectures, the local blood perfusion rate appearing in the Pennes bioheat equation is in a unit of 1/s, or can be interpreted as xx ml of blood supplied to a tissue volume of 1 ml per second. The following lists the blood perfusion rates in various organs or structures in a human body from medical textbooks: brain (50 ml/(min 100g tissue)), kidney (35 ml/(min 100g tissue)), and muscle at rest (3 ml/(min 100g tissue)). Please convert the above local blood perfusion rates into values with the unit of 1/s, therefore, they can be used in the Pennes bioheat equation. The tissue density in a human body is 1050 kg/m³.
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
Problem 1.1MA
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![In medical literatures, local blood perfusion rate is typically presented as xx
ml/(min 100g tissue), in another word, it represents xx ml of blood supplied to a tissue mass of
100 g per minute to satisfy its nutritional needs. As we learned from the course lectures, the
local blood perfusion rate appearing in the Pennes bioheat equation is in a unit of 1/s, or can be
interpreted as xx ml of blood supplied to a tissue volume of 1 ml per second. The following lists
the blood perfusion rates in various organs or structures in a human body from medical
textbooks: brain (50 ml/(min 100g tissue)), kidney (35 ml/(min 100g tissue)), and muscle at rest
(3 ml/(min 100g tissue)). Please convert the above local blood perfusion rates into values with
the unit of 1/s, therefore, they can be used in the Pennes bioheat equation. The tissue density in a
human body is 1050 kg/m³.](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Ff04af373-6616-44d4-9142-5aa7a1930a82%2F794b1459-3f55-4719-9f94-31a61165a806%2Fl3f7rwi_processed.png&w=3840&q=75)
Transcribed Image Text:In medical literatures, local blood perfusion rate is typically presented as xx
ml/(min 100g tissue), in another word, it represents xx ml of blood supplied to a tissue mass of
100 g per minute to satisfy its nutritional needs. As we learned from the course lectures, the
local blood perfusion rate appearing in the Pennes bioheat equation is in a unit of 1/s, or can be
interpreted as xx ml of blood supplied to a tissue volume of 1 ml per second. The following lists
the blood perfusion rates in various organs or structures in a human body from medical
textbooks: brain (50 ml/(min 100g tissue)), kidney (35 ml/(min 100g tissue)), and muscle at rest
(3 ml/(min 100g tissue)). Please convert the above local blood perfusion rates into values with
the unit of 1/s, therefore, they can be used in the Pennes bioheat equation. The tissue density in a
human body is 1050 kg/m³.
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