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England and Wales Court of Appeal (Civil Division) Decisions |
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You are here: BAILII >> Databases >> England and Wales Court of Appeal (Civil Division) Decisions >> Novartis AG & Anor v Johnson & Johnson Medical Ltd & Ors [2010] EWCA Civ 1039 (29 September 2010) URL: http://www.bailii.org/ew/cases/EWCA/Civ/2010/1039.html Cite as: [2010] EWCA Civ 1039, (2011) 118 BMLR 15, [2011] ECC 10 |
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COURT OF APPEAL (CIVIL DIVISION)
ON APPEAL FROM CHANCERY DIVISION
PATENTS COURT
MR JUSTICE KITCHIN
HC 07 C02517, [2009] EWHC 2029 (Pat)
Strand, London, WC2A 2LL |
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B e f o r e :
LORD JUSTICE JACOB
and
LORD JUSTICE PATTEN
____________________
(1) Novartis AG (2) Cibavision AG |
Appellants |
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- and - |
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(1) Johnson & Johnson Medical Limited Also trading as Johnson & Johnson Vision Care (2) Johnson & Johnson Vision Care Inc Also trading as Vistakon |
Respondents |
____________________
WordWave International Limited
A Merrill Communications Company
165 Fleet Street, London EC4A 2DY
Tel No: 020 7404 1400, Fax No: 020 7404 1424
Official Shorthand Writers to the Court)
Mr Simon Thorley QC and Mr Justin Turner QC (instructed by Messrs Freshfield Bruckhaus Deringer) for the respondents
Hearing dates: 5th and 6th July 2010
____________________
Crown Copyright ©
Lord Justice Jacob :
a) Novartis's insufficiency appeal;
b) Contingently on that succeeding, J&J's cross-appeals as to:
i) Obviousness over common general knowledge;
ii) Anticipation by Hopken and Domschke, and;
iii) Obviousness over Lai.
The Common General Knowledge ("cgk")
[36] In the early days contact lenses were made of glass but they had limited success as they were difficult to produce and uncomfortable to wear. In the 1940s a major advance was made with the discovery of the plastic poly(methyl methacrylate) ("PMMA"). This was found to be a suitable hard lens material in terms of its biocompatibility, mechanical and optical properties and relative ease of manufacture. However, PMMA lenses suffered from the drawback that they were still relatively uncomfortable and impermeable to liquids and gases.
[37] In the 1970s a further important advance was made with the invention of polymers known as hydrogels. The first of note was called 2-hydroxyethyl methacrylate ("HEMA"), also known as polyHEMA. The rights to make lenses from this material were purchased by B&L, and in the early 1970s it introduced its polyHEMA "Soflens" contact lens.
[38] Hydrogels are a rather unusual kind of polymer in that they are hydrophilic yet insoluble in water. When placed in water they swell to an extent which is related to the hydrophilicity of the monomers used in their production. Stability is introduced by the use of cross linking monomers such as poly (ethylene glycol) dimethacrylate to produce a three dimensional network. In addition to hydrophilic monomers and cross linkers, a hydrogel formulation may also contain other monomers such as methylmethacrylate ("MMA") as a physical property modifier and solvent to facilitate processing.
[39] A wide range of other hydrophilic monomers were also investigated. In particular, N-vinylpyrrolidone ("NVP") and N,N-dimethyl acrylamide ("DMA") proved useful, as did acid containing monomers such as methacrylic acid ("MAA"). The aim of those working in the field was to develop formulations with a high water content and so also high oxygen permeability. Polymerisation could be initiated using UV light and a photoinitiator.
[40] Although hydrogel based lenses were initially all sold for daily wear, in the early 1980s the FDA approved the use of such lenses for extended periods of wear of up to 30 days. By 1987 it was estimated that they were being used in this way by around 4.1 million Americans. These extended wear lenses were primarily HEMA based and included copolymers with hydrophilic monomers such as DMA, NVP and MAA. Their oxygen permeability (sometimes referred to as "Dk" and measured in barrers or Dk units, and generally using the polarographic method) ranged from about 10 barrers for HEMA lenses to about 30 barrers for lenses made with HEMA and other hydrophilic monomers.
[41] Unfortunately a number of those using these lenses for extended periods of wear began to show clinical complications. Most seriously it was found such users had a significantly greater risk of developing ulcerative keratitis, an extremely painful condition affecting the cornea. As a result, the FDA revised its approval and recommended a maximum extended wear time of seven days. Nevertheless hydrogel lenses, including a lens sold by the defendants under the name Acuvue, remained very popular.
[42] In parallel with the development of hydrogel lenses, scientists were also looking to design lenses made from silicones, materials which combine the elements silicon, carbon and oxygen. One particular class of materials, those made of polydimethylsiloxane ("PDMS"), appeared to be ideal candidates for extended wear lenses because PDMS possesses excellent transparency and high oxygen permeability. However, due to the hydrophobic nature of silicone, these lenses were found to be essentially non wettable (and so required surface treatment) and their elastic nature made them susceptible to corneal adhesion. By 1995, B&L had one surface treated silicone elastomer lens on the market. It was called Silsoft and was used for extended wear in speciality cases only.
[43] A further class of lenses under development at this time also justify a mention at this stage. Rigid gas permeable ("RGP") lenses based on silicone (meth)acrylates were made by combining the stability and processing characteristics of MMA with the high oxygen permeability characteristics of silicone. In particular, it was found that copolymerization of MMA with the silicone 3-(methacryloxy)propyl tris(trimethysiloxyl)silane ("TRIS") and wetting agents such as MAA allowed the production of a lens with good scratch resistance, wettability, dimensional stability and oxygen permeability. As a result, TRIS formed part of the general knowledge as being one of the standard building blocks for silicone containing contact lenses. But RGP lenses were not a success. Their rigid nature means they do not mould to the eye and so are not comfortable. In addition they have a tendency to bind to the cornea if worn overnight.
Some essential characteristics of a contact lens
[44] As a result of all this work, and indeed the further work in relation to silicone hydrogels which I consider later in this section, it was well understood that the design of any contact lens for extended wear must address a number of essential criteria.
[45] The first is oxygen transmissibility. At the outset it is important to note that the oxygen transmissibility of a lens is a measure of the amount of oxygen that can pass through a particular lens and is calculated by dividing the oxygen permeability of the lens material by the lens thickness. Hence oxygen transmissibility (Dk/t) is a characteristic of a particular lens and is expressed in terms of barrers/mm where t is the average thickness of the material. Oxygen permeability, on the other hand, is a characteristic of the material from which the lens is made and does not depend on thickness. It is also expressed in terms of barrers or Dk units, but curiously a barrer in the case of permeability is defined as being an order of magnitude smaller than it is in the case of transmissibility. Hence a lens of a material having a permeability (Dk) of 100 barrers and a thickness of 0.1mm will have a transmissibility (Dk/t) of 100 barrers/mm.
[46] Contact lenses rest on the cornea, a transparent body which transmits and refracts light into the eye. The cornea derives the oxygen it needs directly from the air. If it is deprived of oxygen it becomes hypoxic and begins to swell. In a seminal study published in 1984, Dr Brien Holden and Dr George Mertz investigated the relationship between corneal oedema (swelling) and the oxygen transmissibility of extended wear contact lenses. Holden and Mertz found that the oxygen transmissibility that limits overnight swelling to 4% (the level experienced by a non-contact lens wearer) is 87 barrers/mm. I am satisfied that as a result of this work and a number of similar studies it was a matter of common general knowledge by 1995 that an oxygen transmissibility of in excess of about 70 barrers/mm was necessary to avoid unnatural corneal swelling.
[47] Unfortunately, this degree of oxygen transmissibility could not be achieved with hydrogel lenses. They derive their oxygen permeability from their water content and although it was known it was possible to increase the water content of polyHEMA, and hence also its oxygen permeability, by the incorporation of small amounts of MAA into the polymer, there was still a limit to how much water hydrogel lenses could absorb whilst maintaining their structural integrity and durability. As a consequence, the oxygen transmissibility of hydrogel lenses could not be increased beyond a certain point, commonly from 10 to 30 barrers/mm. Hydrogel lenses could therefore cause a high degree of hypoxia when used in extended wear applications. By contrast, silicone elastomers were known to be highly permeable to oxygen.
[48] The second is movement on the eye. It was understood that in the healthy eye the cornea is covered by a continuous tear film which allows the exchange of ocular fluid, the provision of metabolic products to the cornea and the removal of metabolic by-products from the cornea. The ideal contact lens therefore allows the eye to maintain a tear film between the lens and the cornea, and this in turn was known to be affected by the degree to which the lens was free to move on the eye. One of the factors which was known to affect the ability of a lens to move on the eye was the hydrophilicity of the lens surface. The hydrogel lenses fulfilled this requirement admirably. But unfortunately the silicone elastomer lenses did not. They suffered both from adhesion of lipid deposits to the lens surface and adhesion of the lens to the cornea. As a result, silicone elastomer lenses were sometimes surface treated to make their surfaces more hydrophilic, but they were still prone to deposits of lipids and proteins on the lens surface and to adhesion to the cornea. It was also found that the surface treatments had a tendency to degrade fairly rapidly, giving poor vision and comfort.
[49] The third is wettability. This is related to the lens characteristics which permit movement on the eye. The surfaces of the lens must be wettable so that a smooth, stable and continuous tear film is formed both behind and on front of the lens when it is worn, so ensuring corneal health, good vision and comfort. Again this was not a problem with the hydrogel lenses but it was a serious issue with silicone elastomer lenses, and one which was only partially addressed by the use of surface treatments.
[50] In addition to these characteristics, a successful lens must also be optically transparent and biocompatible, possess chemical and thermal stability and have suitable mechanical properties, including (in the case of hydrogels) a low modulus of elasticity for patient comfort and a high tear strength for durability.
Silicone hydrogels
[51] In the 1970s scientists began to combine silicone materials with hydrogels with the aim of obtaining the beneficial properties of both types of material. The theory was straightforward: such lenses would have the oxygen transmissibility characteristics of the silicones and the wettability and comfort of the hydrogels. One of the pioneers was Dr Karl Mueller of Ciba-Geigy who made a copolymer from a silicone containing macromer and the monomers HEMA, NVP and MMA which collectively introduced a hydrophilic quality. Others followed, including the inventors of Keogh, Chang and Lai. I have no doubt that by 1995 the general concept of making a silicone hydrogel lens from hydrophilic monomers such as DMA, NVP and HEMA and silicone monomers such as TRIS and PDMS was a matter of common general knowledge.
[52] The production of a satisfactory extended wear lens did not, however, prove straightforward. One of the problems facing researchers was that the two different kinds of monomers are generally immiscible, and copolymerisation can result in opaque phase separated materials. This was addressed, at least to some extent, by the preparation of intermediate siloxane macromers containing hydrophilic groups. Several approaches were known, including synthesis of hydrophilic TRIS derivatives and of siloxanes containing hydrophilic end caps, blocks or side chains which aid their miscibility with the hydrophilic monomers and so assist in the formation of a clear polymer.
[53] Another problem was achieving the right balance between wettability and oxygen permeability. It was appreciated that, in contrast to conventional hydrogels where the oxygen permeability is derived from the water content and so the two increase in proportion to each other, the opposite is true in the case of the silicone hydrogels. Here the presence of water decreases the oxygen permeability of the polymer composition. This relationship was well understood and is illustrated in this figure taken from an article published by Dr Jay Kunzler and Dr Joseph McGee (both of B&L) in August 1995:
[54] Kunzler and McGee reported, as indeed is evident from the graph, that silicone hydrogels could be formulated to achieve a wide range of water content and oxygen permeability, with Dk values in the 50-200 barrer range. As is also apparent from the graph, lenses made of these materials could have a satisfactory oxygen permeability and a reasonably high water content of say 30%, which, as Professor Valint explained, was sufficient to get movement on the eye. However, an obstacle remained and that was how to achieve a surface chemistry which provided good biocompatibility and wetting characteristics. The hydrophobic surface characteristics of the lens, derived from its silicone content, made it difficult to maintain an adequate tear film, despite the lens itself having a reasonable, or even high, water content. This phenomenon was not well understood in 1995 but appeared to arise from the tendency of hydrophilic siloxane groups to dominate the surface chemistry of any resultant lens. Considerable research was therefore undertaken by workers in the field to find a polymer structure which would produce a single clear material from which to make a homogenous, clear lens whilst incorporating the oxygen permeability of silicone elastomers, but retaining the biocompatibility and wettability of conventional hydrogels.
[55] The issue of wettability was therefore fundamental to the development of an extended wear lens. The evidence established that the skilled person would have been aware of the possibility of surface treatment, using techniques such as plasma coating and plasma oxidation, to improve the wettability of a silicone hydrogel lens. Professor Valint considered this was the case, it was something to which B&L resorted and, as will be seen, it was described by Chang. Similarly, Dr Port agreed that plasma treatment in general, including those plasma treatments carried out by a Dr Yasuda and published in 1985, were well known to the person skilled in the art by 1995. Professor Koßmehl also accepted that the concept of surface treatment was well known.
[56] The effectiveness of surface treatment in the context of silicone hydrogels had not, however, been established. Professor Valint agreed that the ordinary skilled person would not have had experience of the successful modification of lens surfaces to make an extended wear lens. Professor Koßmehl explained that the skilled person would have considered that the then known surface treatments for silicone elastomers were short lived. Indeed the Kirk-Othmer encyclopaedia, published in 1995 and which was accepted to contain the common general knowledge, recited that although surface treatments, both physical and chemical, had demonstrated the ability to alter the specific properties of contact lens surfaces, most treatments "fail as a result of alteration of bulk lens properties, instability of surface treatment, or poor ocular compatibility." Moreover, it continued, "Research is expected to continue in the characterization and modification of contact lens surfaces".
[57] Overall, Professor Valint agreed with Professor Koßmehl's opinion that in 1995 the area of silicone hydrogels was still experimental. Research had been going on for 20 years and many different materials had been proposed, but none had been proven. There were no commercially available silicone hydrogel lenses and significant challenges remained.
[58] By 1995 there were two principal ways of making soft contact lenses, namely lathing and cast moulding. In the case of the former, rods of polymer are formed and these are then cut into buttons and lathed to form lenses. In the case of the latter, the liquid mixture of silicone monomers and macromers and hydrophilic monomers is placed into a mould and cured, typically with UV radiation. The mould is then opened and the lens extracted, washed and treated as necessary. I am satisfied that the skilled person would have been well aware of both techniques in 1995. The evidence also established that the manufacturing method may affect the chemical and morphological structure of a lens and the topography of the finished lens material.
The Patent Claim
(A) An ophthalmic lens having ophthalmically compatible inner and outer surfaces,
(B) wherein said ophthalmic lens is selected from the group consisting of contact lenses for vision correction, contact lenses for eye colour modification, ophthalmic drug delivery devices and ophthalmic wound healing devices,
(C) said lens being suited to extended periods of wear in continuous, intimate contact with ocular tissue and ocular fluids,
(D) said lens comprising a polymeric material,
(E) which has high oxygen permeability and high ion permeability,
(F) said polymeric material being formed from polymerizable materials comprising:
(a) at least one oxyperm polymerizable material as defined in section I of the description, and
(b) at least one ionoperm polymerizable material, as defined in section I of the description,
(G) wherein said lens allows oxygen permeation in an amount sufficient to maintain corneal health and wearer comfort during a period of extended continuous contact with ocular tissues and ocular fluids, and
(H) wherein said lens allows ion or water permeation in an amount sufficient to enable the lens to move on the eye such that corneal health is not substantially harmed and wearer comfort is acceptable during a period of extended, continuous contact with ocular tissue and ocular fluids,
(I) wherein said ophthalmic lens has an oxygen transmissibility as defined in section I of the description of at least about 70 barrers/mm and
(J) an ion permeability characterized either by
(1) an Ionoton Ion Permeability Coefficient of greater than about 0.2 x 10-6 cm²/sec, or
(2) an Ionoflux Diffusion Coefficient of greater than about 1.5 x 10-6 mm²/min,
wherein said coefficients are measured with respect to sodium ions, and according to the measurement techniques described in sections II.F.1 and II.F.2 of the description respectively.
A wide range of materials which may be polymerized to form a polymer displaying a relatively high oxygen diffusion rate therethrough. In addition these materials must be relatively ophthalmically compatible.
That is all there is to it – "a high relatively oxygen diffusion rate" and "relatively ophthalmically compatible." Each of these has "woolly" limits. As to a "high oxygen diffusion rate" there is no further definition as such at all. Indirectly there is something of a limit because the definition says something about the "oxygen transmissibility" of the ultimate lens. This depends not only on the inherent nature of the material (the oxygen diffusion rate) but also the thickness of the lens. [39] says ""the oxygen transmissibility (Dk/t) of the lens is preferably at least 70 barrers/mm". So even this is not precise.
[23] A "polymerizable material which is capable of polymerizing to form a polymer having a high ion permeability" as used herein, refers to monomers, oligomers, macromers and the like, and mixtures thereof, which are capable of polymerizing with like or unlike [polymerizable] materials to form a polymer which displays a relatively high rate of ion or water permeation therethrough. For convenience of reference, these materials will be referred to herein as "ionoperm polymerizable materials" and the resultant polymers will be referred to as "ionoperm polymers."
Although the rate of permeation is to be "relatively high" one is not told in relation to what.
Ionoperm polymerizable materials include a wide range of materials which may be polymerized to form a polymer displaying a relatively high ion diffusion rate therethrough. In addition these materials must be relatively ophthalmically compatible.
"Ophthalmically compatible" as used herein refers to a material or surface of a material which may be in intimate contact with the ocular environment for an extended period of time without significantly damaging the ocular environment and without significant user discomfort.
no generally accepted threshold of ophthalmic compatibility, that different wearers can have different responses and that even the claimants' FND commercial product can cause damage to the eye. As for corneal swelling, paragraph [0040] of the Patent contemplates corneal swelling of less than about 8% using preferred extended wear contact lenses and claim 47 limits the degree of permissible swelling to less than about 8%, suggesting that a greater degree of swelling may be acceptable in the case of claim 1.
The claims shall define the matter for which protection is sought. They shall be clear and concise and supported by the description.
Unfortunately failure to comply with Art. 84 is not itself a ground of invalidity. However some of the grounds which are available for an invalidity attack overlap with Art.84. The jurisprudence of the Boards of Appeal has had to deal with undue width of claim by resorting to either the requirement of non-obviousness or that of sufficiency or both. As will be seen I think they come into play here.
I believe the Patent is directed to a team interested in making workable prototypes of lenses which can then be carried forward into more extensive clinical trials. Such a team would carry out small scale clinical assessments, using a minimum of from 6 to 10 patients but reasonably up to about 30, and look to mean and median responses for the group, just as the defendants did in seeking to reproduce the prior art.
[313] Conducting clinical trials of a new lens is by no means a straightforward matter. Dr Brennan gave evidence in his third report that a trial of two new lenses over a 24 hour period with up to thirty subjects per lens would cost a great deal of money. In cross examination he put it at somewhere in the region of 100,000-140,000 US dollars. A trial for that number of subjects for an extended period of up to 30 days would obviously be rather more.
Another object of the invention is to provide an ophthalmic lens capable of extended continuous wear periods of at least 24 hours without substantial adverse impact on ocular health or consumer comfort, and more preferably [longer].
[066] An Ionoflux Diffusion Coefficient of greater than about 6.4. x 10-6 mm2/min is preferred for achieving sufficient on-eye movement. More preferably, the Ionoflux Diffusion Coefficient is greater than about 2.6 x 10-6 mm2/min, while most preferably the Ionoflux Diffusion Coefficient is greater than about 15. x 10-6 mm2/min. It must be emphasized that the Ionoflux Diffusion Coefficient correlates with ion permeability through the lens, and thereby is a predictor of on-eye movement (my italics).
[72] An Ionoton Ion Permeability Coefficient, P, of greater than about 0.2 x 10-6 cm2/sec is preferred, while greater than about 0.3 x 10-6 cm2/sec is more preferred, and greater than about 0.4 x 10-6 cm2/sec is most preferred. It must be emphasized that the Ionoton Ion Permeability Coefficient correlates with ion permeability through the lens, and thereby is a predictor of on-eye movement (again my italics).
[256] Next, it is apparent that the ion permeability thresholds of the claims are very different depending on whether the parameter is measured using the Ionoton or Ionoflux technique. To recap, the Ionoton threshold of claim 1 is 0.2 x 10-6 cm²/sec, or 2 x 10-7 cm²/sec whereas the Ionoflux threshold is 1.5 x 10-6 mm²/min, or 2.5 x 10-10 cm²/sec, a difference of three orders of magnitude. This, said Professor Freeman, is very surprising because both measure ion permeability and so one would expect the thresholds to be about the same. I agree.
[257] Dealing first with the Ionoton technique, Table E of the Patent sets out Ionoton values which are said to have been measured on the particular lenses listed in the left hand column of the table. This constitutes the only experimental evidence in the Patent of how the threshold Ionoton values relate to "on-eye movement." … The Patent specifies that "the lowest value of Ionoton Ion Permeability Coefficient for which a lens moves on the eye is 0.25x10-3 cm2/sec," and "the highest value of Ionoton Ion Permeability Coefficient for a lens which is bound on the eye is 0.008x10-3 cm2/sec." Professor Freeman explained, and I agree, that based on the description and the experimental evidence presented in Table E, the Ionoton Ion Permeability Coefficient threshold for on-eye movement of a contact lens must lie somewhere between 0.008x10-3 cm2/sec and 0.25x10-3 cm2/sec.
[258] This deduction, whilst undoubtedly sound on the basis of the data presented, faces major problems. The first is that all the lenses in Table E for which on eye movement was recorded had Ionoton values in excess of the ion diffusion coefficient of sodium chloride in water, which is 2.1 x 10-5 cm2/sec at 35°C. This is wholly improbable, as Professor Freeman explained. He is not aware of any literature source which reports an ion permeability value for a polymer which is higher than the transport rate of sodium chloride through water.
[259] Second, the values in table E differ by orders of magnitude from ion permeability values given for contact lenses in the literature.
[260] Third, the Ionoton permeability threshold of claim 1 of the Patent is 0.2x10-6 cm2/sec. This is 40 times lower than 0.008x10-3 cm2/sec, which is the lowest conceivable threshold value based on the data in Table E, and is 1,250 times lower than 0.25x10-3 cm2/sec, which corresponds to the lowest Ionoton value for which there was on-eye movement, based on the data in Table E. Thus, as Professor Freeman put it, the claimed value is markedly lower than the on-eye movement threshold which the inventors have deduced from the experimental measurements which they have purported to carry out and is unsupported by any experimental evidence in the Patent. It was unclear to him, and it is unclear to me, from where the Ionoton Ion Permeability Coefficient threshold of claim 1 is derived. Indeed, Table E appears to show that a lens with an Ionoton permeability value above the claimed threshold did not move on the eye.
[261] Dr Port initially expressed the opinion that Professor Freeman's approach was fundamentally flawed as a matter of science. However, in cross examination he accepted that it was confusing that there was such a large difference between the threshold of claim 1 and the Ionoton values which are said to have been determined by the inventors experimentally and are set out in Table E. He also had no scientific explanation for these values being so high.
[262] In contrast to the position in relation to the Ionoton permeability values, at least the claimed threshold for Ionoflux Ion Permeability Coefficient bears a relationship to the teaching in the Patent. The experimental data are set out in Table F. As I have explained, the Patent teaches that the lowest value of the Ionoflux Ion Permeability Coefficient for which a lens moved on the eye was 2.6 x 10-6 mm2/min; and the highest value of the Ionoflux Ion Permeability Coefficient for which a lens bound to the eye was 1.5 x 10-6 mm2/min. The Ionoflux limitation in claim 1 corresponds to that lower value of 1.5 x 10-6 mm²/min, or 2.5 x 10-10 cm²/sec.
[263] Nevertheless, the difference between the claim thresholds for Ionoton and Ionoflux permeability is very striking. Professor Freeman described them as "vastly different". In fact, the Ionoton threshold is 800 times greater than the Ionoflux threshold. But the position is yet worse when the reported experimental values are compared. The lowest Ionoflux value for which movement on the eye is reported is 2.6 x 10-6 mm²/min or 4.33 x10-10 cm²/sec. By contrast, the lowest Ionoton value for which movement on the eye is reported is 0.25 x10-3 cm²/sec – a difference of more than 500,000 times and such that Professor Freeman considered the two values to be irreconcilable.
[264] Indeed the Ionoflux threshold of all the claims is so low that, as Professor Freeman demonstrated in Figure 8 of his first report, the prior art contact lenses such as example 3 of Chang, example 4 of Lai and example VI of Keogh all soar above even the highest threshold of claim 17.
[265] What then is the explanation for this discrepancy between the Ionoton and Ionoflux permeability values? No doubt it is attributable in part to the improbably high experimental values of Ionoton permeability to which I have referred. But it also seems tolerably clear the Ionoflux values are set far too low to provide any meaningful threshold.
[298] The previous disclosure will enable one having ordinary skill in the art to practice the invention. In order to better enable the reader to understand specific embodiments and the advantages thereof, reference to the following examples is suggested.
Novartis has rightly pointed out that the patent specification contains many examples of lenses that have the required ophthalmic compatibility and which the person skilled in the art can easily reproduce.
If that accurately records what was submitted, then Novartis are saying different things in this court to what they were saying to the Dutch Court. I hope that is not so. Whether or not there was this inconsistency the Dutch Court clearly thought the examples "worked." That lay at the heart of its decision to reject the sufficiency attack. What the Court would have said if it had known what has emerged in these proceedings – that even Novartis has no idea whether the "examples" or any of them, "work" - one can only guess.
However the patent specification contains many examples of the manufacture of lenses having the claimed structural features and functions.
The Bundespatentgericht also took it that the examples worked. That court found on that basis, not surprisingly, that Hopken and Domschke (which it labelled K5 and K6) anticipated. It is worth nothing that the Court clearly also had severe doubts as to whether the patent was sufficient although in the end it did not decide this point. It said:
The question, whether or not the teaching of the patent in suit, as a result of the special wording of the claim, the breadth of the claim and features 2, 4, 7 and 8 of the claim [corresponding to features A, C, G and H of the breakdown used above] which can only be determined by clinical tests, indeed represents an invitation to carry out a research programme or whether it really constitutes a Reach-Through-claim (cf. EPO 10637/06 of February 3, 2009) and whether enablement must be denied for this reason – irrespective of the principles of the Taxol decision may remain undecided.
.. the description of the patent in suit contains a plurality of specific examples of manufacture of lenses according to the invention.
[42] The ratios of oxyperm to ionoperm materials may vary substantially, depending on the selected balance of oxygen permeability and ion permeability for the chosen end use of the molded polymeric article. Preferably the volumetric ratio of oxyperm to ionoperm material (including water) in the fully hydrated lens is about 40 to about 60 to about 60 to about 40. [a little more detail about ratios by weight adds no more]
2.2.1 … In the Board's judgment the criteria for determining the sufficiency of the disclosure are the same for all inventions, irrespective of the way in which they are defined, be it by way of structural terms of their technical features or by their function. In both cases the requirement of sufficient disclosure can only mean that the whole subject-matter that is defined in the claims, and not only a part of it, must be capable of being carried out by the skilled person without the burden of an undue amount of experimentation or the application of inventive ingenuity.
The peculiarity of the "functional" definition of a component of a composition of matter resides in the fact that this component is not characterised in structural terms, but by means of its effect. Thus this mode of definition does not relate to a tangible component or group of components, but comprises an indefinite and abstract host of possible alternatives, which may have quite different chemical compositions, as long as they achieve the desired result. Consequently, they must all be available to the skilled person if the definition, and the claim of which it forms a part, is to meet the requirements of Article 83 or 100(b) EPC. This approach is based on the general legal principle that the protection covered by a patent should correspond to the technical contribution to the art made by the disclosure of the invention described therein, which excludes that the patent monopoly be extended to subject-matter which, after reading the patent specification, would still not be at the disposal of the skilled person. …
There cannot, of course, be a clear-cut answer to the question of how many details in a specification are required in order to allow its reduction to practice within the comprehensive whole ambit of the claim, since this question can only be decided on the basis of the facts of each individual case. Nevertheless, it is clear that the available information must enable the skilled person to achieve the envisaged result within the whole ambit of the claim containing the respective "functional" definition without undue difficulty, and that therefore the description with or without the relevant common general knowledge must provide a fully self-sufficient technical concept as to how this result is to be achieved.
[5] Article 83 EPC requires an invention to be disclosed in a manner sufficiently clear and complete for it to be carried out by a person skilled in the art. As made clear in [citation omitted] the extent to which an invention is sufficiently disclosed is highly relevant when considering the issue of support within the meaning of Article 84 EPC, because both these requirements reflect the same general principle, namely that the scope of a granted patent should correspond to its technical contribution to the state of the art. Hence it follows that, despite being supported by the description from a purely formal point of view, claims may not be considered allowable if they encompass subject matter which in the light of the disclosure provided by the description can be performed only with undue burden or with application of inventive skill. As for the amount of technical detail needed for a sufficient disclosure, this is a matter which depends on the correlation of the facts of each particular case with certain general parameters, such as the character of the technical field, the date on which the disclosure was presented and the corresponding common general knowledge, and the amount of reliable technical detail disclosed in a document [citation omitted]. In certain cases a description of one way of performing the claimed invention may be sufficient to support broad claims with functionally defined features, for example where the disclosure of a new technique constitutes the essence of the invention and the description of one way of carrying it out enables the skilled person to obtain without undue burden the same effect of the invention in a broad area by use of suitable variants of the component features [citation omitted]. In other cases, more technical details and more than one example may be necessary in order to support claims of a broad scope, for example where the achievement of a given technical effect by known techniques in different areas of application constitutes the essence of the invention and serious doubts exist as to whether the said effect can readily be obtained for the whole range of applications claimed [citation omitted]. However, in all these cases, the guiding principle is always that the skilled person should, after reading of the description, be able to readily perform the invention over the whole area claimed without undue burden and without needing inventive skill [citation omitted]. On the other hand, the objection of lack of sufficient disclosure presupposes that there are serious doubts, substantiated by verifiable facts, in this respect [citation omitted].
1.2 … The board however observes that the definition "amorphous silica" comprises a host of possible chemical compounds which may or may not satisfy the multiplicity of parameters defined in the claims of the requests at issue and in this context, the question arises whether the patent contains sufficient information about how these parameters are to be reliably achieved so that the person skilled in the art has at his disposal a process which leads him in a direct way to the amorphous silicas claimed.
[1.8] ….. However, this reasoning which can be accepted only for the two examples, does not hold good for the other claimed but non-exemplified amorphous silicas and in the absence of any specific recipe concerning the preparation of such silicas, the problems concerning the stirring speed still remain for silicas claimed over the whole range.
[1.9] The skilled person is thus confronted with the uncontested fact that he has a lot of process variables affecting the claimed parameters, but once he has encountered failure in one parameter value, there is no clear guidance enabling him to adjust the multitude of process steps in order to arrive with certitude at silicas meeting the parameter requirements defined in claim 1 of both requests at issue. Even though a reasonable amount of trial and error is permissible when it comes to assessing sufficiency of disclosure, there must still be adequate instructions in the specification, or on the basis of common general knowledge, leading the skilled person necessarily and directly towards success, through evaluation of initial failures. This is not the case here, since the preparation of the amorphous silicas claimed is made dependent on the adjustment of different process parameters for which no guidance is given in the patent in suit, so that the broad definition of an amorphous silica as presently claimed is no more than an invitation to perform a research program in order to find a suitable way of preparing the amorphous silicas over the whole area claimed.
[1.10] It follows from the above, that the principle underlying Article 83 EPC that the skilled person should be given sufficient guidance for performing the invention without undue burden over the whole range claimed is thus not fulfilled.
[291] In my judgment it emerges from this evidence that the Patent does not enable the skilled person to predict whether any particular lens will satisfy the requirements of the claims without clinical testing. Moreover, and subject to the general teaching to which Professor Koßmehl referred, and which I consider immediately below, the Patent provides no practical assistance how to find potentially suitable polymer compositions beyond those described in families A to D.
[297] In summary, these teachings were either matters of common general knowledge which did not permit the production of an extended wear silicone hydrogel lens without invention or are not such as to provide any general teaching as to how such lenses can be made without undue effort.
[312] I have largely addressed these in considering other aspects of the teaching. But to summarise, they remain subject to the overriding criticisms that first, the Patent does not teach which materials within the specific families and examples described are suitable for the production of ophthalmically compatible extended wear lenses; and second, the Patent does not permit the skilled person to make a prediction that any lens is likely to be ophthalmically compatible over a period of extended wear. I am satisfied that both of these criticisms are sound.
[315] First, the Ionoton Ion Permeability Coefficient values taught by the Patent and set by the claims are extremely confusing and of little or no practical assistance to the skilled person seeking to make an ophthalmically compatible lens suitable for extended wear.
[316] Second, the threshold Ionoflux Ion Permeability Coefficient values taught by the Patent and set by the claims are so low that that they will easily, if not inevitably, be satisfied. As such, they provide little or no practical assistance to the skilled person seeking to make an ophthalmically compatible lens suitable for extended wear.
[317] Third, the Patent does not enable the skilled person to make any prediction as to whether a lens is ophthalmically compatible over a period of extended wear without clinical testing; nor can he make any prediction as to whether a particular silicone hydrogel formulation is suitable for making such a lens.
[318] Fourth, the skilled person cannot even make any prediction as to whether any and, if so which, of the lenses described in the Patent are ophthalmically compatible over a period of extended wear; nor can he make a prediction as to whether any, and if so which, of the formulations described in the Patent are suitable for making such a lens.
[319] Fifth, the Patent does not teach which, if any, of the lenses or formulations described in the Patent have continuous or co-continuous phases or pathways and provides no or no adequate teaching as to how to produce lenses having such co-continuous phases or pathways in any event.
[320] Sixth, it follows there is no or no adequate teaching in the Patent of any unifying characteristic or principle of general application which would enable the skilled person to predict which silicone hydrogel formulations are likely to be useful for producing an ophthalmically compatible lens suitable for extended wear. The teaching is not such that success may be achieved and ensured.
[321] Seventh, it would involve a considerable amount of work and great expense to test any reasonable number of lenses on a reasonable number of subjects to ascertain whether they are ophthalmically compatible over a period of extended wear.
[322] Eighth, in the light of the foregoing and the absence of such a unifying characteristic or principle of general application, it would involve a research programme to identify silicone hydrogel formulations which are useful for producing an ophthalmically compatible lens suitable for extended wear. I have made a like finding in relation to the allegation that it was obvious how to produce such a formulation in the light of the common general knowledge and the cited art.
i) J&J had not done experiments to prove that the instructions in the Patent could not be used to produce a lens complying with the claim. In this connection the Judge had failed to apply the proper onus of proof, which lay on J&J.ii) Predictability of success in producing a lens which "worked" was not a relevant consideration to insufficiency;
iii) The Judge had applied the wrong test for sufficiency, mixing in irrelevant considerations of obviousness or anticipation.
iv) The Judge had overlooked the fact that J&J were running two inconsistent cases, one of obviousness and the other of sufficiency. There was evidence from J&J's witnesses that a lens falling within the claim could be made and tested and accordingly the case of insufficiency must fail.
Those in the art had attempted for some time to produce a silicone hydrogel lens suitable for extended wear by balancing water content against oxygen permeability.
What the Patent teaches is not about using different pairs of polymers from the kinds tried in the past, it is about using ion permeability rather than water content as a predictor of on-eye movement using the same general kinds of polymer. Since people were not getting "success" with the old method, one can fairly say that "success" was not likely with just any pair of claimed polymers. So there is no missing evidential proof. Proof did not require the experiments said by Mr Waugh to be essential.
i) Even if true the Patent does not tell you how usefully to use this information. This is because the claimed level of ion permeability is so meaningless. Moreover even if you found you had no on-eye movement and used the idea of increasing the ion permeability so as to get it, the Patent does not help you maintain oxygen permeability at the same time – there is no help on finding the balanceii) In particular the examples of the Patent provide no useful information actually as to how to use ion permeability to make a useful prediction as to on-eye movement.
iii) In any event even when you have got on eye movement and sufficient oxygen permeability you still have to test on people to see if it "works". If it does not, the Patent provides no more help. Do you (i) change a polymer or the pair of polymers, (ii) change the proportions, or (iii) try a variety of surface treatments, or (iv) some combination of any of the foregoing? The skilled person is not "given sufficient guidance for performing the invention without undue burden over the whole range claimed".
iv) Moreover using ion permeability as a predictor is not all that different from the prior art notion of using water content as a predictor. The Judge so found, saying in [254]:
I am satisfied there is a broad correlation between water content and ion permeability of silicone hydrogels.Mr Thorley took us to the evidence upon which that finding was based so as to emphasise it. Of particular importance was that of Prof. Freeman whom the Judge found to be an "outstanding witness." The finding has profound significance. It means that by and large there is no difference between water content and ion permeability as a predictor for on-eye movement. So the teaching of the Patent in practice adds nothing more to help you find a pair of polymers which have on-eye movement. If you do not get it with a particular pair, the Patent suggests an increase in ion permeability might give it, the prior art suggests increased water content might give it– and these amount to the same thing. Neither help on the problem of balance, and neither solve the problem of ophthalmic compatibility which, beyond avoiding lack of on-eye movement and providing sufficient oxygen, remains purely empirical.v) That ion permeability is not a key to success is also borne out by the fact that no one in the art has subsequently accepted that is so, or has used ion permeability as way to find a successful extended wear lens.
vi) Finally in relation to ion permeability it should be remembered that the claimed monopoly goes well beyond anything to do with it. The claim covers a lens made from any pair of polymers in proportions provided the lens "works" (if necessary using a surface treatment). The defendant need not have (and may well not have) arrived at his successful product ever having even attempted to measure or use ion permeability. He may well have used water content as a guide on the way but he will still be caught if his product "works."
Lord Justice Patten:
Lord Justice Ward: