The reaction of Cp*Zr(BH3CH3)3 with an excess amount of trimethylamine in a toluene solution yields the hypercarbon-containing complex ({Cp*Zr(BH3CH3)}(μ-H)2{Cp*Zr(BH3CH3)}(μ-H){Cp*Zr(BH3CH3)})(μ-κ2C,H:κ1C:κ2C,H-CHBH3), 1. To our knowledge, this is the first example in which a hypercoordinated carbon-containing complex was prepared from the reaction of a hydroborate complex with a Lewis base. The reaction of 1, NaH, and [N(CH3)4]Cl produces the anionic product [N(CH3)4][({Cp*ZrCl}{(μ-H)2{Cp*Zr(BH3CH3)}}2)(μ-κ2C,H:κ1C:κ2C,H-CHBH3)], 2, whereas the reaction of 1 with B(C6F5)3 produces the hydride abstraction cationic product [({Cp*Zr(BH3CH3)}{(μ-H){Cp*Zr(BH3CH3)}}2)(μ-κ2C,H:κ1C:κ2C,H-CHBH3)][HB(C6F5)3], 3. The further reaction of 3 with [N(CH3)4]Cl and NaOH produces the neutral complex ({Cp*Zr(BH3CH3)}((μ-H){Cp*Zr(BH3CH3)})2)(μ-κ2C,H:κ1C:κ2C,H-CHBH3)(μ3-X) (X = Cl (4), OH (5)). Single-crystal X-ray structures of 1, 2, 3, 4, and 5 reveal a pentacoordinated carbon atom, which coordinates to a boron atom, a hydrogen atom, and three Zr atoms in each complex. The geometry around the hypercarbon in each complex can be best described as either distorted trigonal bipyramidal or distorted square pyramidal. The μ3-bridging Cl– ligand in 4 and OH– ligand in 5 bond to three Zr atoms on the opposite side of the hypercarbon. These hypercarbon-containing complexes were further characterized by elemental analysis, infrared spectroscopy, and NMR spectroscopy. Formations of 2–5 confirm the robust framework of the hypercarbon when undergoing reactions.