All The Claims

What is claimed is:

1. A recombinant viral vector capable of expressing a gene in a selected host cell or tissue comprising:
a) at least a portion of the genome of a DNA virus which exhibits tropicity for said selected host cell or tissue, which portion is capable of infection of said selected host cell or tissue; said genome having been modified to have a level of virulence less than the level of virulence present in a wild type virulent strain of the virus from which said vector is derived; and
b) a gene operatively linked thereto wherein said gene is capable of expression in said selected host cell or tissue after infection of said selected host cell or tissue.
2. The recombinant vector of claim 1, wherein said vector further comprises a DNA sequence containing a nonviral initiation site of DNA synthesis operatively linked to said gene for amplification of said gene.
3. The recombinant vector of claim 1, wherein said DNA virus is a double-stranded neurotropic virus, said human gene is the gene for hypoxanthine-guanine phosphoribosyltransferase, and said vector further comprises a promoter sequence of DNA for promoting expression of said gene.
4. The recombinant vector of claim 3, wherein said DNA virus is herpes simplex virus and said vector is synthesized by a process comprising:
a) cloning a fragment containing a herpes virus thymidine kinase promoter into a suitable plasmid;
b) linearizing said plasmid with Bg1 II to obtain plasmid DNA;
c) obtaining a fragment containing human HPRT cDNA, and blunt-ending and ligated said fragment to BamH1 linkers to form a ligatable fragment;
ligating said ligatable fragment to said linear plasmid DNA to form a recombinant plasmid containing a TK promoter-HPRT minigene;
linearizing and recombining said recombinant plasmid with an intact wild-type herpes virus genome to form recombinant viral progeny containing the TK promoter-HPRT minigene.
5. The recombinant vector of claim 3, wherein said portion of said viral genome contains a deletion in a viral gene necessary for replication of said genome.
6. The recombinant vector of claim 3, wherein said DNA sequence containing said nonviral initiation site is of murine origin.
7. A method of viral-mediated gene therapy for the treatment of a selected host organism comprising the steps of:
a) providing at least a portion of a genome of a DNA virus, said portion being capable of infecting cells of said selected host organism;
b) operatively linking a human gene to said portion to form a recombinant viral vector, said gene being capable of expression in said host cell after infection of said cell by said vector;
c) modifying said recombinant viral vector to have a level of virulence less than the level of virulence present in a wild type virulent strain from which said portion of said genome is derived; and
d) directly contacting said selected host organism with sufficient quantity of said viral vector and for a time effective for said viral vector to infect said organism.
8. The method of claim 7, further comprising the step of providing said recombinant vector with a nonviral site of initation of DNA synthesis.
9. The method of claim 8, wherein said portion of said genome of said virus is replication-defective.
10. The method of claim 9, wherein said virus is a double-stranded neurotropic virus and said site of nonviral initiation is contained within as autonomous replicating sequence of murine orgin.
11. The method of claim 10, wherein said virus is a herpes simplex virus, said gene is the gene for hypoxanthine-guanine phosphoribosyltransferase, and said recombinant vector further comprises a viral promoter sequence for promoting expression of said gene.
12. A method for providing means for amplification of a gene carried on a recombinant viral vector comprising the steps of:
a) providing at least a portion of the genome of a virus, said portion being capable of infecting a host organism;
b) operatively linking a human gene to said portion to form a recombinant viral vector, wherein said gene is capable of expression in said host organism after infection of said organism by said vector; and
c) providing a nonviral site of initiation of neuclic acid synthesis for amplification of said gene.
13. The method of claim 12, wherein said method further comprises the step of modifying said portion of said genome of said virus replication-defective.
14. The method of claim 12, wherein said nonviral site of initiation resides on an autonomous replicating sequence of nucleic acids.
15. The method of claim 14, wherein said virus is a double stranded DNA virus which exhibits tissue-tropism, said human gene codes for an enzyme which is selectable in culture, and said autonomous replicating sequence is of murine orgin.
16. The method of claim 15, wherein said virus is herpes simplex virus, said gene is the gene for hypoxanthine-guanine phosphoribosyltransferase and said recombinant vector further comprises a DNA sequence for the herpes simplex thymidine kinase promoter operatively linked thereto.

The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.

1. A method of designing an integrated circuit, comprising:
receiving a functional description of said integrated circuit;
placing and routing, using a computer, a plurality of synthesized entities to create a physical design implementation for said integrated circuit, wherein each synthesized entity of said plurality of synthesized entities comprises a portion of said functional description of said integrated circuit that has been synthesized into a gate-level implementation; and
manipulating said plurality of synthesized entities to facilitate said physical design implementation satisfying a plurality of design constraints, wherein said manipulating comprises using physical design information of said physical design implementation to ensure satisfying said plurality of design constraints.
2. The method of claim 1, wherein said manipulating said plurality of synthesized entities further comprises:
performing integrated circuit chip level analysis for area, timing and power constraints using aggregate characteristics of said plurality of synthesized entities; and
modifying said plurality of synthesized entities using said integrated circuit chip level analysis to satisfy said design constraints.
3. The method of claim 1, wherein said manipulating said plurality of synthesized entities comprises: merging a first synthesized entity with a second synthesized entity.
4. The method of claim 1, wherein said manipulating said plurality of synthesized entities comprises: splitting synthesized entity into two or more synthesized entities.
5. The method of claim 1, wherein said manipulating said plurality of synthesized entities comprises: moving synthesized entity from one location to another location.
6. The method of claim 1, wherein said manipulating said plurality of synthesized entities comprises: changing size of one or more synthesized entities.
7. The method of claim 1, wherein said manipulating said plurality of synthesized entities comprises: modifying said gate-level implementation of synthesized entity.
8. The method of claim 1, wherein said manipulating said plurality of synthesized entities comprises: resynthesizing said functional description of synthesized entity into a new gate-level implementation.
9. The method of claim 1, further comprising:
providing a global level view of said physical design implementation using said plurality of synthesized entities to enable said global level view, wherein said global level view ensures satisfying said design constraints.
10. A computer-readable storage device comprising a plurality of computer-executable instructions stored therein, said computer-executable instructions comprising:
instructions to receive a functional description of an integrated circuit;
instructions to place and route a plurality of synthesized entities to create a physical design implementation for said integrated circuit, wherein each synthesized entity of said plurality of synthesized entities comprises a portion of said functional description of said integrated circuit that has been synthesized into a gate-level implementation; and
instructions to manipulate said plurality of synthesized entities to facilitate said physical design implementation satisfying a plurality of design constraints, wherein said instructions to manipulate comprise instructions to use physical design information of said physical design implementation to ensure satisfying said plurality of design constraints.
11. The computer-readable storage device of claim 10, wherein said instructions to manipulate said plurality of synthesized entities further comprise:
instructions to perform integrated circuit chip level analysis for area, timing and power constraints using aggregate characteristics of said plurality of synthesized entities;
instructions to modify said plurality of synthesized entities using said integrated circuit chip level analysis to satisfy said design constraints; and
instructions to resynthesize said functional description of synthesized entity into a new gate-level implementation.
12. The computer-readable storage device of claim 10, wherein said instructions to manipulate said plurality of synthesized entities comprise:
instructions to modify said gate-level implementation of synthesized entity.
13. The computer-readable storage device of claim 10, wherein said instructions to manipulate said plurality of synthesized entities comprise:
instructions to merge a first synthesized entity with a second synthesized entity.
14. The computer-readable storage device of claim 10, wherein said instructions to manipulate said plurality of synthesized entities comprise:
instructions to split synthesized entity into two or more synthesized entities.
15. The computer-readable storage device of claim 10, wherein said instructions to manipulate said plurality of synthesized entities comprise:
instructions to move synthesized entity from one location to another location.
16. The computer-readable storage device of claim 10, wherein said instructions to manipulate said plurality of synthesized entities comprise:
instructions to change size of one or more synthesized entities.
17. The computer-readable storage device of claim 10, wherein said computer-executable instructions further comprise:
instructions to provide a global level view of said physical design implementation using said plurality of synthesized entities to enable said global level view, wherein said global level view ensures satisfying said design constraints.
18. An electronic design tool comprising:
a functional description analyzer configured to facilitate partitioning a functional description of an integrated circuit into a plurality of entities based on a plurality of rules; and
an entity engine configured to create and manage a plurality of synthesized entities, wherein each synthesized entity comprises a portion of said functional description of said integrated circuit that has been synthesized into a gate-level implementation.
19. The electronic design tool of claim 18, further comprising: a physical design engine configured to use said synthesized entities to create a physical design implementation for said integrated circuit that meets a plurality of design constraints.
20. The electronic design tool of claim 18, wherein if said design constraints are met, physical design information of said physical design implementation is useable for a final physical design implementation for said integrated circuit.

1. A fuel pressure regulation system comprising a fuel supply line fluidly connecting a fuel supply to an inlet of a transfer pump, a transfer pressure fuel line fluidly connecting an outlet of the transfer pump to an inlet of a high pressure fuel pump, a fuel filter positioned in the transfer pressure fuel line, a fuel spill line fluidly connecting a fuel pressure regulator to the transfer pressure fuel line, a fuel return line fluidly connecting the fuel pressure regulator and the fuel supply line and a control fuel line fluidly connecting the fuel pressure regulator to the transfer pressure fuel line, characterised in that the fuel spill line is fluidly connected to the transfer pressure fuel line at a point between the outlet of the transfer pump and the fuel filter.
2. A fuel pressure regulation system as claimed in claim 1 wherein the control fuel line is fluidly connected to the transfer pressure fuel line at a point between the fuel filter and the inlet to the high pressure pump.

The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.

1. A dual mode wheelchair comprising:
at least one fore wheel mounted on a fore axis and at least one rear wheel mounted on a rear axis, a distance between the fore axis and the rear axis defining a wheelbase of the wheelchair;
wherein the wheelbase is alterable between a short wheelbase providing a maneuverable mode of the wheelchair and a long wheelbase providing a travel mode of the wheelchair;
wherein a center of gravity of the wheelchair when occupied in the maneuverable mode is higher than a center of gravity of the wheelchair when occupied in the travel mode;
the dual mode wheelchair further comprising a sub-frame upon which the at least one rear wheel is mounted, and a seat frame upon which the at least one fore wheel is mounted;
wherein the seat frame is movably mounted to the sub-frame to provide for alteration of the wheelbase between the maneuverable mode and the travel mode; and
wherein the movable mounting of the seat frame to the sub-frame comprises a sliding mount.
2. The dual mode wheelchair as claimed in claim 1, wherein the wheelchair provides a reclined seating position in the travel mode, and an upright seating position in the maneuverable mode.
3. The dual mode wheelchair as claimed in claim 1, further providing for operation of the wheelchair in at least one intermediate position between the maneuverable mode and the travel mode.
4. The dual mode wheelchair as claimed in claim 1, wherein a sliding mount attachment of the seat frame is proximal to a rear of the seat frame, and wherein the sliding mount provides for the sliding mount attachment of the seat frame to travel forwardly and downwardly when the wheelbase is lengthened from the maneuverable mode to the travel mode.
5. The dual mode wheelchair as claimed in claim 4, wherein the rear of the seat frame is lower relative to a fore portion of the seat frame when in the travel mode, providing a reclined seating position of the wheelchair in the travel mode.
6. A dual mode wheelchair comprising:
at least one fore wheel mounted on a fore axis and at least one rear wheel mounted on a rear axis, a distance between the fore axis and the rear axis defining a wheelbase of the wheelchair;
at least one guide wheel rearward of the at least one rear wheel;
wherein the wheelbase is alterable between a short wheelbase providing a maneuverable mode of the wheelchair and a long wheelbase providing a travel mode of the wheelchair;
wherein a center of gravity of the wheelchair when occupied in the maneuverable mode is higher than a center of gravity of the wheelchair when occupied in the travel mode.
7. The dual mode wheelchair as claimed in claim 6 wherein the at least one guide wheel includes one guide wheel, and wherein the guide wheel is positioned substantially centrally between the sides of the wheelchair.
8. The dual mode wheelchair as claimed in claim 6, wherein the wheelchair is articulated.
9. A dual mode wheelchair frame comprising:
a first frame portion for mounting at least one fore wheel on a fore axis; and
a second frame portion for mounting at least one rear wheel on a rear axis, a distance between the fore axis and the rear axis defining a wheelbase of the dual mode wheelchair frame;
wherein the first frame portion is movably mounted to the second frame portion to provide for alteration between a short wheelbase providing a maneuverable mode of the wheelchair frame and a long wheelbase providing a travel mode of the wheelchair frame; and
wherein a center of gravity of the wheelchair frame when occupied in the maneuverable mode is higher than a center of gravity of the wheelchair frame when occupied in the travel mode;
wherein the movable mounting of the first frame portion to the second frame portion comprises a sliding mount.
10. The dual mode wheelchair frame as claimed in claim 9, wherein the wheelchair frame provides a reclined seating position in the travel mode, and an upright seating position in the maneuverable mode.
11. The dual mode wheelchair frame as claimed in claim 9, further providing for operation of the wheelchair frame in at least one intermediate position between the maneuverable mode and the travel mode.
12. The dual mode wheelchair frame as claimed in claim 9, wherein a sliding mount attachment of the first frame portion is proximal to a rear of the first frame portion, and wherein the sliding mount provides for the sliding mount attachment of the first frame portion to travel forwardly and downwardly when the wheelbase is lengthened from the maneuverable mode to the travel mode.
13. The dual mode wheelchair frame as claimed in claim 12, wherein the rear of the first frame portion is lower relative to a fore portion of the first frame portion when in the travel mode, providing a reclined seating position of the wheelchair frame in the travel mode.
14. A dual mode wheelchair frame comprising:
a first frame portion for mounting at least one fore wheel on a fore axis; and
a second frame portion for mounting at least one rear wheel on a rear axis, a distance between the fore axis and the rear axis defining a wheelbase of the dual mode wheelchair frame;
wherein the first frame portion is movably mounted to the second frame portion to provide for alteration between a short wheelbase providing a maneuverable mode of the wheelchair frame and a long wheelbase providing a travel mode of the wheelchair frame; and
wherein a center of gravity of the wheelchair frame when occupied in the maneuverable mode is higher than a center of gravity of the wheelchair frame when occupied in the travel mode; and
wherein the second frame portion further comprises at least one mount for a guide wheel rearward of the at least one rear wheel.
15. The dual mode wheelchair frame as claimed in claim 14, wherein the wheelchair frame is articulated.