If $f$ is holomorphic, so is its derivative $f'$.

$\gdef\CC{\mathbb{C}}$ $\gdef\spaces#1{~ #1 ~}$

If $f: U \to \CC$ is holomorphic and $D(z,r)$ is any open disk contained in $U$, then the power series expansion for $f$ centered at $z$ converges in all of $D(z,r)$.

Let me pause to give a cute example application of this theorem. Consider the power series

$$ F(z) \spaces= \sum_{n \ge 0} F_n \cdot z^n $$

where $F_n$ is the $n^{th}$ Fibonacci number. Then the recurrence relation $F_{n+2} = F_{n+1} + F_n$ and normalization $F_0 = F_1 = 1$ translate into the relation

$$ F(z) \spaces= zF(z) + z^2F(z) + 1 $$

Using this, we find that $F(z)$ is the power series expansion of

$$ F(z) \spaces= \frac{1}{1-z-z^2} $$

around $0$. This function $F$ is holomorphic everywhere except when $1-z-z^2=0$ i.e. when $z=\frac{1\pm\sqrt{5}}{2}$. From this we can conclude that the radius of convergence of our series $\frac{1-\sqrt{5}}{2}$. Indeed, $F$ is holomorphic in the disk with radius $\frac{\sqrt{5}-1}{2}$, so the above theorem tells us that the radius of convergence is at least $\frac{\sqrt{5}-1}{2}$; but on the other hand, the function $F$ tends to $\infty$ as $z$ approaches $\frac{1-\sqrt{5}}{2}$, and a power series can’t tend to $\infty$ inside a region where it is defined since a power series is continuous; thus the radius of convergence is also at most $\frac{\sqrt{5}-1}{2}$, whence the claim. This tells you something about the order of growth of the $F_n$.

$\gdef\CC{\mathbb{C}}$

Let $U \in \CC$ be open, and $z \in U$. Suppose $f: U \backslash \{z\} \to \CC$ is holomorphic, and is bounded in some disk around $z$. Then $f$ extends uniquely is holomorphic on all of $U$.

So merely the fact of $f$ being bounded around $z$ implies something much stronger.