Australian medical patents granted in the United States in 1984-1999

Abstract

We chose to study all patents for inventions (utility patents) granted in the United States to Australian residents. These patents are economically more significant than patents granted in Australia, as the increased cost and effort of patenting in another country is thought to filter out trivial inventions.⁵ Because of the importance of the US market, the US is also the first country where multinational corporations submit their patent applications outside the patent's country of origin.⁶ Thus, Australian patents in the US are arguably the most important subset of Australian patents in other countries.⁷ Our aim was to describe Australian medical patents and to compare them with non-medical patents.

Sources of data

• year of patent being granted;

• US patent registration number;

• title of patent;

• all listed inventors and assignees and their country of residence; and

• number of citations of scientific literature.

When required for classifying patents, the patent abstracts or full patents were examined on the Internet (using the US patent registration number) at either the US Patent and Trademark Office Web Patent Database Centre,¹⁰ or the Delphion (formerly IBM) Intellectual Property Network.¹¹

Categorisation of medical patents

• managing patients and their illnesses, such as drugs, diagnostic tests, surgical instruments, and rehabilitation devices (dental technologies were excluded);

• preventing illness, such as sunscreen lotion; or

• medical research, such as laboratory instruments. Generic technologies used in other fields, such as information technology, were excluded.

Patents were classified as medical, possibly medical or non-medical after reading the title and the name of the assignees (owners). For all patents labelled as possibly medical, we read the abstract, and if necessary the complete patent, to properly classify the patent.

Medical patents related to biotechnology¹² were identified separately, and included devices, processes, DNA sequences, transgenic animals and manufacturing processes in the medical industry. Biotechnology patents related to other industries, such as agriculture, mining and food processing, were excluded.

Describing inventors and assignees

The assignees on each patent were categorised as a business, university, government, research institute, CRC, non-government organisation, technology transfer office, or individual. Categorising was usually straightforward using the name of the assignee, but, if there was uncertainty, a search was made on the Internet using the search engine Dogpile.¹⁴

Data analysis

Ethical issues

Results

Trends in medical patenting

Comparison of medical and non-medical patents

• more likely to have multiple inventors listed, with a median of two inventors per medical patent versus one per non-medical patent (P < 0.001, Box 2); and

• twice as likely to be part of an international collaboration, with co-inventors who are residents of other countries in 21% (275/1308) of medical and 10% (649/6527) of non-medical patents (P < 0.001, Box 3).

Most US patents listing Australian inventors have either an Australian inventor or assignee owning the patent (68% for medical and 81% for non-medical patents) (Box 3). The technology most likely to arise from another country is that owned by an assignee in another country and listing an inventor from another country. Thus, 15% of medical and 7% of non-medical patents in our study may have originated outside Australia (Box 3).

Patents are either assigned, usually to an organisation, or unassigned (thus owned by the inventor). We found 82% of medical patents were assigned, compared with 69% of non-medical patents (P < 0.001, Box 2). For assigned patents, both medical and non-medical patents usually have one assignee (Box 2). For these assigned patents, there were three large differences, with medical patents being (Box 4):

• less likely to be owned by a business;

• four times more likely to be owned by a university; and

• 40 times more likely to be owned by a research institute.

Medical patents were three times as likely as non-medical patents to quote from published scientific articles. Sixty per cent (785/1308) of medical patents cited one or more scientific publications, compared with only 23% (1475/6527) of non-medical patents (P < 0.001).

Characteristics of medical patents

Just 14 organisations own 33% (438/1308) of medical patents; six of these organisations are Australian universities and their affiliated institutions (Box 6). Surprisingly, 20% (264/1308) of medical patents were owned by just five organisations: the University of Melbourne, Telectronics, the Commonwealth Scientific and Industrial Research Organisation (CSIRO), Biotech Australia, and the University of New South Wales.

The three most common types of medical technologies are cardiac pacemakers (7%), syringes or parenteral drug delivery technology (4%), and cochlear ear implants (3%).

Principal findings

As expected, Australia's comparative technological advantage is found mainly in mining and agriculture. This is similar to other resource-abundant OECD countries like Canada, Finland and Norway.^5,7 However, our study, along with others,^7,17 indicates a shift in Australia to patenting in higher technologies. Our study suggests that medical technology, especially medical biotechnology, is an increasingly important part of Australia's intellectual property portfolio. This may explain why Australia appears to be developing a technological advantage in biotechnology and pharmaceuticals.¹⁷ To place this trend in a global perspective, our study would need to be repeated for other, especially OECD, countries.

There is a dip in the total number of US patents granted to Australian inventors from 1990 to 1993 (Box 1), possibly reflecting the economic recession at the time. Interestingly, the trend in medical and medical biotechnology patents did not show this decrease, suggesting that development of such technology may be more resistant to downturns in the economy. Another feature was the 51% jump in the number of US patents granted to Australian inventors from 1997 to 1998 -- possibly a flow-on from the 54% increase in the number of patent applications filed by Australians in the US between 1994 and 1998¹⁸ (noting that it usually takes two years from lodging a patent application until it is granted¹⁹). This trend coincides with increased research and development spending in Australia, particularly by business (which unfortunately declined in 1996-97).²⁰ However, these changes may also reflect increased processing of patent applications by the US Patent and Trademark Office⁷ -- the overall number of utility patents issued jumping 32% from 111 983 in 1997 to 147 520 in 1998.¹⁶

Our study lends support to recent findings of the importance of university-based research in underpinning high-technology patents and industries.^1,21 Universities and their affiliated institutions:

• make up more than a third of the most prolific patenting organisations;

• own an increasing proportion of US patents granted to Australian inventors; and

• are the source of 97% of the scientific articles cited in Australian medical patents.¹⁷

Our data also support the emerging ideas on the importance of clusters of co-located industries and universities where collaboration and competition act as constant spurs to innovation, such as is seen in Silicon Valley in California.²¹ In Australia, such clusters appear to be growing in Melbourne and Sydney for industries in biotechnology and electromedical devices. This is demonstrated by examining the prolific inventors and their assignees, indicating varied links between industry and publicly funded institutions.

Strengths and weaknesses of the study

Classification of country of origin: We classified patents as Australian if any inventor was an Australian resident. This may result in the inclusion of technology originating in another country but which had an Australian inventor working on it (estimated to be about 15% for medical and 7% for non-medical patents).

Definition of medical patents: Given the absence of any published guidelines, it could be debated whether certain technologies are really "medical" (such as those related to optometry and sunscreen lotions) and whether dental technologies should have been excluded.

Classification of assignees as "business": Assignees with a business-type suffix (ie, "Pty Ltd", "Ltd", "Corp", "Inc", "NV", "AG" and "GMBH"), unless detected through searches on the Internet as belonging to another category such as a technology transfer organisation, would have been misclassified as a business.

It is difficult to predict whether the first two potential biases could alter our conclusions. The third may lead to an overestimation of the number of patents owned by business. When identifying the country of origin of a patent, the main convention is to use the residency of the inventor^16,17 rather than assignees, partly because a large proportion of patents are unassigned (29% in our study).

Like other technology or innovation indicators, patent statistics have advantages and disadvantages.^22,23 Our study treats all patents as being of equal importance; however, a patent's commercial value can vary enormously.^23,24 Furthermore, patent data do not capture all new technology, as some may not be patentable, and patenting can vary with economic conditions and with the strategic concerns of companies.^23,24 For example, patenting as a means of protecting intellectual property is very important for the pharmaceutical industry but of little relevance to the rubber industry.²⁴ In addition, the difficulty when describing patents owned by business is that many are granted under the names of subsidiaries and divisions that are different from the names of parent companies. Some companies even actively hide emerging technologies under different company names, so-called "submarine" patents.^5,25

Possible mechanisms and implications for policymakers

To foster the growing culture of enterprise and innovation within academia,⁴ it may be worth considering a reward for the prolific inventors and assignees. Such rewards may encourage other inventors and promote inventors as role models for other scientists.

Acknowledgements

References

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Authors' details

Reprints will not be available from the authors.
Correspondence: Dr E Mattes, Visiting Research Fellow, TVW Institute for Child Health Research, Division of Population Sciences, 100 Roberts Road, Subiaco, WA 6008.
emattesATcyllene.uwa.edu.au

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