Low pressure insufflation manifold assembly for surgical gas delivery system

What is claimed is: 1. A manifold assembly for a surgical gas delivery system comprising: a) a three-dimensional manifold body having a horizontal top surface and a plurality of vertical side surfaces including a first side surface and a second side surface, and including an inlet port for receiving insufflation gas from a gas source by way of a high pressure regulator, a first outlet port for delivering the insufflation gas to a first access port and a second outlet port for delivering the insufflation gas to a second access port, wherein the inlet port is located on the first side surface of the manifold body, and the first outlet port and the second outlet port are located on the second side surface of the manifold body; b) a first outlet line valve located on the top surface of the manifold body and communicating with the first outlet port through internal passageways defined within the manifold body, wherein the first outlet line valve includes an electro-mechanical valve actuator for dynamically controlling a flow of the insufflation gas to the first access port; c) a second outlet line valve located on the top surface of the manifold body and communicating with the second outlet port through the internal passageways defined within the manifold body, wherein the second outlet line valve includes an electro-mechanical valve actuator for dynamically controlling the flow of the insufflation gas to the second access port; and d) a primary proportional valve located on the top surface of the manifold body and communicating with the first outlet line valve and the second outlet line valve through the internal passageways defined within the manifold body for maintaining a constant pressure within the manifold body upstream from the first outlet line valve and the second outlet line valve. 2. The manifold assembly recited in claim 1 , wherein the manifold body further includes an exhaust port for venting a gas to an atmosphere, wherein a ventilation exhaust valve is operatively associated with the exhaust port, and wherein the ventilation exhaust valve includes an electro-mechanical valve actuator for dynamically controlling the venting of the gas from the exhaust port. 3. The manifold assembly recited in claim 2 , wherein the manifold body further includes a safety vent port for releasing the gas to the atmosphere, and a low pressure safety valve is operatively associated with the safety vent port, and wherein the low pressure safety valve is a mechanical valve for controlling the release of the gas from the safety vent port to limit a maximum intermediate pressure within the manifold assembly in an event of a power interruption, a pressure controller malfunction, or if another valve sticks in an open position. 4. The manifold assembly recited in claim 3 , wherein the primary proportional valve includes an electro-mechanical valve actuator for dynamically controlling a flow of the insufflation gas to the first outlet line valve and the second outlet line valve. 5. The manifold assembly recited in claim 4 , wherein the manifold body includes a communication port for communicating with a pair of blocking valves remote from the manifold assembly, wherein a blocking valve pilot valve is operatively associated with the communication port located upstream from the primary proportional valve, and wherein the blocking valve pilot valve includes an electro-mechanical valve actuator for dynamically controlling a flow of the gas therethrough. 6. The manifold assembly recited in claim 4 , wherein the manifold body includes a pressure sensor port downstream from the primary proportional valve and upstream from the first outlet line valve and the second outlet line valve. 7. The manifold assembly recited in claim 1 , wherein the electro-mechanical valve actuator of the first outlet line valve and the electro-mechanical valve actuator of the second outlet line valve are each a motorized rotary actuator, which each include an axial drive screw operatively associated with a vertical valve stem. 8. The manifold assembly recited in claim 1 , wherein the manifold body includes a first patient pressure sensor port downstream from the first outlet line valve and a second patient pressure sensor port downstream from the second outlet line valve for measuring abdominal pressure. 9. The manifold assembly recited in claim 1 , wherein the manifold body includes a first pressure sensor port and a second pressure sensor port upstream from the first outlet line valve and the second outlet line valve to measure a pressure differential used to infer a total gas flow rate from the manifold body to a body cavity of a patient. 10. The manifold assembly recited in claim 1 , wherein the first access port is a valve sealed access port and the second access port is a gas sealed access port. 11. A manifold assembly for a surgical gas delivery system comprising: a) a three-dimensional manifold body having a horizontal top surface and a plurality of vertical side surfaces including a first side surface and a second side surface, and including an inlet port for receiving insufflation gas from a gas source by way of a high pressure regulator, a first outlet port for delivering the insufflation gas to a valve sealed access port and a second outlet port for delivering the insufflation gas to a gas sealed access port, wherein the inlet port is located on the first side surface of the manifold body, and the first outlet port and the second outlet port are located on the second side surface of the manifold body; b) a first outlet line valve located on the top surface of the manifold body and communicating with the first outlet port through internal passageways defined within the manifold body, wherein the first outlet line valve includes a motorized rotary valve actuator for dynamically controlling a flow of the insufflation gas to the valve sealed access port; c) a second outlet line valve located on the top surface of the manifold body and communicating with the second outlet port through the internal passageways defined within the manifold body, wherein the second outlet line valve includes a motorized rotary valve actuator for dynamically controlling the flow of the insufflation gas to the gas sealed access port; and d) a primary proportional valve located on the top surface of the manifold body and communicating with the first outlet line valve and the second outlet line valve through the internal passageways defined within the manifold body for maintaining a constant pressure within the manifold body upstream from the first outlet line valve and the second outlet line valve. 12. The manifold assembly recited in claim 11 , wherein the manifold body further includes an exhaust port for venting a gas to an atmosphere, wherein a ventilation exhaust valve is operatively associated with the exhaust port, and wherein the ventilation exhaust valve includes a motorized rotary valve actuator for dynamically controlling the venting of the gas from the exhaust port. 13. The manifold assembly recited in claim 12 , wherein the manifold body further includes a safety vent port for releasing the gas to the atmosphere, and a low pressure safety valve is operatively associated with the safety vent port, and wherein the low pressure safety valve is a mechanical valve for controlling the release of gas from the safety vent port to limit a maximum intermediate pressure within the manifold assembly in an event of a power interruption, a pressure controller malfunction, or if another valve sticks in an open position. 14. The manifold assembly recited in claim 13 , wherein the primary proportional valve includes a mo