There is only one definition for continuity: $f$ is continuous at $1$ if and only if $f(x)\to f(1)$ when $x\to1$, that is, for every positive $\varepsilon$, there exists a positive $\delta$ such that $|x-1|\le\delta$ implies $|f(x)-f(1)|\le\varepsilon$.
In your case $f(1)=1$ and $|f(x)-1|=|x-1|\cdot|x^2+x+1|\le3|x-1|$ if $0 and $|f(x)-1|=3|x-1|$ if $x>1$. Hence, for every positive $\varepsilon<1$, there exists $\delta>0$ such that $|x-1|\le\delta$ implies $|f(x)-f(1)|\le\varepsilon$. (I am sure you can find a suitable $\delta$.) This proves that $f$ is continuous at $1$.
Maybe you can attack differentiability now. First, that $f$ is differentiable at $1$ means that $f(x)=f(1)+(x-1)a+(x-1)\varepsilon(x)$ for a given $a$ and a given function $\varepsilon$ such that you-know-what holds. You probably already have an idea for $a$ so all you have to do now is to figure out what is the function $\varepsilon$ and to apply all your powers to show that $\varepsilon$ behaves well...