Problem 1:
Solve the following expression: $\sqrt{16} + \sqrt{9} \cdot \sqrt{4} - \sqrt{25} \div \sqrt{5}$.

Solution:
First, let's simplify each radical term individually:
$\sqrt{16} = 4$, since 4 squared is 16,
$\sqrt{9} \cdot \sqrt{4} = 3 \cdot 2 = 6$, and
$\sqrt{25} \div \sqrt{5} = 5 \div \sqrt{5}$.

Now, we can simplify the expression further:
$4 + 6 - 5 \div \sqrt{5}$,
$4 + 6 - \frac{5}{\sqrt{5}}$.

Next, rationalize the denominator of the fraction by multiplying the numerator and denominator by $\sqrt{5}$:
$4 + 6 - \frac{5 \cdot \sqrt{5}}{\sqrt{5} \cdot \sqrt{5}}$,
$4 + 6 - \frac{5 \cdot \sqrt{5}}{5}$.

Simplify the expression:
$4 + 6 - \sqrt{5}$,
$10 - \sqrt{5}$.

Therefore, the solution to the expression $\sqrt{16} + \sqrt{9} \cdot \sqrt{4} - \sqrt{25} \div \sqrt{5}$ is $10 - \sqrt{5}$.

Problem 2:
Solve the following equation: $2 \cdot \sqrt{9} - (\sqrt{25} - 1) \div \sqrt{2}$.

Solution:
First, simplify each radical term individually:
$\sqrt{9} = 3$, since 3 squared is 9,
$\sqrt{25} = 5$, and
$\sqrt{2}$ remains the same.

Now, we can solve the equation further:
$2 \cdot 3 - (5 - 1) \div \sqrt{2}$,
$6 - 4 \div \sqrt{2}$.

Next, divide 4 by $\sqrt{2}$:
$6 - \frac{4}{\sqrt{2}}$,
$6 - \frac{4 \cdot \sqrt{2}}{\sqrt{2} \cdot \sqrt{2}}$,
$6 - \frac{4 \cdot \sqrt{2}}{2}$,
$6 - 2 \cdot \sqrt{2}$.

Therefore, the solution to the equation $2 \cdot \sqrt{9} - (\sqrt{25} - 1) \div \sqrt{2}$ is $6 - 2 \cdot \sqrt{2}$.