The need for patent valuation: importance of patents

The effective patent term is short. It starts from the date the drug is registered, which is much earlier than the date the actual drug enters the market. The average effective patent life for medicines is 11.5 years following commercial launch. Also, the initial investment in R&D (research & development) is high, so the patent rights play a more crucial role in recouping the investments in new drugs. The average cost to develop a new medicine has been estimated at upward of US$2.6 billion, ^{Grabowsky (2002}, ²⁰⁰³, ²⁰¹⁴, ²⁰¹⁷⁾, according to an analysis conducted by the Tufts Center for the Study of Drug Development. The drug is covered under patent protection, which means that only the pharmaceutical company that holds the patent is allowed to manufacture, market the drug and eventually make a profit from it. The drug development process is known to be complex, costly and time-consuming, ^{Di Masi et al., (2003)}.

Patents and revenues

Patented drugs contribute over 70% of total drug sale revenues. The moment a drug goes off patent, companies suffer a noticeable impact on revenues. There was a bumpy ride for the industry in 2011-2012 when 16 major patents expired. This amounted to about $12 billion of 2011 revenues and over $30 billion of 2012 revenues, ^{Pharma (2014)}. The lifetime of the patent varies between countries and also between drugs. Since the company applies for a patent long before the clinical trial to assess a drug’s safety and efficacy has commenced, the effective patent period after the drug has finally received approval is often around seven to twelve years.

Once the patent has expired, the drug can be manufactured and sold by other companies. At this point, the drug is referred to as a generic drug. According to guidelines in most countries, including those from the US FDA, generic drugs have to be identical to the branded drug in terms of efficacy, safety, usage, route of drug administration, pharmacokinetics and pharmacodynamics, ^{Di Masi et al. (2003)}.

The phases of a drug development

The drug development phase is a long and demanding process that requires several different tests and phases cleared in order to obtain a final approval. Each phase can be seen as an option for you at the end of the phase have to take a decision on whether to discard the project or continue developing it (exercise the option). The decision is based on the prospects of the drug (the underlying asset) which test results reveal at the end of each phase.

The drug development process is very risky because it is difficult to know how long and how much it will take to get a phase approved as the research requirements are very different for different disease areas, ^{Di Masi et al., (2003)}, ^{Pharma (2014)} and ^{Grabowsky (2002}, ²⁰⁰³, ²⁰¹⁴, ²⁰¹⁷⁾. The following exposs the process of developing a new drug.

The discovery/lead optimization phase

The first phase is the discovery phase or lead optimization phase, ^{F&D. U.S. (2015}, ²⁰¹⁶⁾. A drug development often starts by either identifying a new biochemical compound to find out if it has a positive effect on a known disease or trying to find a cure or vaccine for a disease by testing different biochemical compounds on it.

On a more technical level, the biochemical compound is tested on human tissue in order to get an indication of an effect. If this indication is positive, the work for a chemical structure will continue so as to end up with a useable drug that has a therapeutic effect. These primary tests are purely in vitro tests, which mean that they are not performed on living organisms.

The preclinical stage

The next step in the process is the preclinical stage where the lead compound has been identified. In the preclinical stage, the scientists still do not have a lot of information on how it affects the targeted disease. The main goal at this stage is to get more information about the drug and its effects. At the same time, it is also important to obtain information about the negative things, most importantly, if any serious side effects exist. If all of these studies look good, the company will file an “Investigational New Drug” (IND) to the authorities to get approved for phase I. The IND contains all the information obtained at this stage along with a future plan for the clinical phases, which is the next step in the development process. At this stage, the research studies are still not performed on humans, but on animals.

Clinical Research

Drugs are tested on people to make sure they are safe and effective: Phase I, Phase II, and Phase III.

- Phase I

In phase I, the testing is performed on a small (20-80) group of persons, who at this point are healthy people. ^{F&D. U.S. (2015)}. The aim of the research studies in phase I is to evaluate the effects the drug has on human beings and compare them to those found in the preclinical phase. But the most important thing is how well the drug handles the transition from being applied to animals to now getting applied on real human beings. Therefore it would be ideal that the picture of the test results obtained in the preclinical phase resembles the picture obtained when the drug is applied to human beings. The test results obtained in this phase are the foundation for the work that continues in phase II.

- Phase II

Phase II continues the work begun in phase I, but the tests in phase II include a larger group of test persons (100-300). Furthermore, a part of these people suffers from the disease in question. This is necessary in order to track the effects that the drug has on both sick people and healthy people and to find out how the drug acts in different settings. Phase II is often the phase where most applications are dropped (if the drug enters the preclinical phase). This is often because the drug does not have the efficacy. The rejection of the drug development project is often done by the company’s management at this stage, and not by the authorities.

- Phase III

The objective of phase III is to look at the long-term effects as well as the effects on a much larger scale. The group of test persons is increased severely now (1,000-3,000). This is done to increase the documentation of the effects found in the previous phases and to confirm the effectiveness of the drug, while still monitoring side effects, toxic level and so on. This is among the reasons for why the industry uses this divided phase process so it is possible to discard a project at an early stage due to bad test results.

Approval

When a company has completed all the phases it is time to file the entire information as a “New Drug Application”, NDA, to the European Medicines Evaluation Agency, ^{Harvard Law Review (1995)}, EMEA. Then it is up to the authorities to decide whether the test results and the documentation are enough to approve the drug. Sometimes the documentation is not thorough enough, and the authorities will demand extra studies completed before a final decision can be made. In some cases, the authorities will accept the drug but still demand more test results. Therefore we can sometimes experience the use of a phase IV that covers this exact situation.

Patent

FDA monitors all drug and device safety once products are available for use by the public. The patent is used from the beginning of the process of research and development to protect the drug, ^{Sereno (2010)}. The patent period is normally 20 years, but with an R&D period of normally 12 years, it only leaves 8 years with market exclusivity. Normally patent protection is sought in those countries where the company in question wants to market the drug. So for a larger company with consumers all over the world, the patent seeking process could end up as a rather expensive cost. Patent protection is basically a method for companies to devote many resources to the R&D process without the risk of generic competition when completed. The 20-year period is estimated to be long enough for the companies to cover all the R&D costs experienced during the development phases and still make a profit. After the 20-year period, the patent expires and the chemical structure is released on the market. With the chemical structure in hand, it is possible for other companies to make a generic copy of the product and sell it at a far lower price because they only need to be concerned about the manufacturing costs and not any R&D expenditures. The number of patents that companies seek varies a great deal and is, of course, dependent on the size of the company R&D expenditures, ^{F&D. U.S. (2015}, ²⁰¹⁶⁾.

Net present value of an investment project

Net present value of an investment project, I₀, with expected cash flows CF_i and brought to present value at a rate represented by the weighted average cost of capital (WACC), r_WACC, It is given by the following equation:

The Net present value, NPV, has the limitation of not providing flexibility in their decision-making of investors because it’s a deterministic model with n cash flows. Therefore, for an investment project be feasible, the present value of expected cash flows discounted at r_WACC should be greater than initial investment to keeping alive the investment option. ^{Luehrman (1998)} states that this methodology is now obsolete and it´s necessary to use other methodology. For this reason is necessary searching another alternative of valuation of the investment projects that give de investor more flexibility in decision-making.

Real Options Method in the evaluation of investment projects

Real Options analysis allows you to value risk, creating strategies to mitigate risk and how to position yourself to take advantage of risk, ^{Mun (2002}, ²⁰⁰⁶⁾. The technique of real options valuation assumes that the world is characterized by change, uncertainty and competitive interactions between companies; and that their managers have the flexibility to review and adapt future decisions in response to changing circumstances. Real options incorporate this learning model, akin to having a strategic roadmap.

Real options give the executive the right, but not the obligation, to conduct certain business initiatives; which means added value for the investor, i.e. they provide a more informed decision on strategic projects, this is one of the reasons that real options valuation is a useful and robust tool used in valuation of investment projects and situations in which corporate managers are prepared to make the right decisions at the right time, (^{Dixit and Pindyck,1994}), ^{Stewart Myers} was one of the first to use the term of Real Options in 1984, in his book “Finance Theory and Financial Strategy”; the pioneers of the use of this technique were the developers of mining and petroleum projects; development and production of mines or oil wells could be visualized as a series of linked options.

A lot of researchers have deepened in the field of real options, such as ^{Brach Marion A. (2003)}, Mascareñas, ^{Rubio, and Lamothe, (2010)}, ^{Lamothe et al., (2004)}, ^{Bailey, W. et al. (2004)}, ^{Kulatilaka (1995)}, ^{Smith Rob (2002)}, ^{Boer (2002)}, ^{Mun (2002}, ²⁰⁰⁶, ²⁰¹⁰⁾, ^{Arnold (2014}, ²⁰⁰⁴⁾ and ^{Cruz-Aranda et al. , (Fall 2016)} among others.

Myron S. Scholes and Fisher Black were in the early 70´s in the MIT Sloan School of Management with its famous ^{Black & Scholes formula (1973a}, ^{b, Nobel laureate in economics in 1997)} for European options. An important contribution to this formula is by Robert C. Merton with his argument of not arbitrage, so they were first to provide a closed-form solution for financial options, as well as ^{Cox et al (1979)} who introduced an equivalent discrete binomial valuation approach that has proved to be very powerful in complex options settings.

The transition from Capital Markets’ theory to Corporate Finance’ theory occurred in 1977, when ^{Stewart C. Myers} published his idea a real option can be thought as a promising investment opportunity that can be experiment a wholly unforeseen event at valuation time, stemming from existing company’s capabilities and its core competencies.

^{Trigeorgis (1993)} discusses general properties concerning the nature of options interactions and the valuation of capital budgeting projects possessing flexibility in the form of multiple real options.

It was not until 1996 when they held the first successful attempts to make the theory of real options accessible to financial practitioners when ^{Lenos Trigeorgis} published his book Real Options, Managerial Flexibility, and Strategy in Resource Allocation. ^{Amram and Kulatilaka (1999)} in turn presented the subject from a more practical point of view in his book, also called Real Options. Meanwhile, ^{Copeland and Antikarov (2003)} offered a less quantitative approach to applied real options. ^{Chevalier-Roignant and Trigeorgis (2011)} added game theory with real options valuation in their planning to help predict how competitors would play certain strategies so companies are more flexible to know how to react. According to ^{Rubio and Lamothe (2010)} technique, real options turns out to be the best alternative for the valuation of companies related to innovation, such as the pharmaceutical industry, since this technique, despite its complexity, collects randomness and flexibility that characterize this sector.

The utility of real options are not only in valuing a firm through its strategic business options but also as a strategic business tool in capital investment make decisions, ^{Arnold (2014)}. ^{Ioulianou S. et al (2017)} contribute to multinational and real options theories by considering the role of firm heterogeneity in real options awareness for multinational corporations. They test the joint impact of real options awareness and multinational on firm value using an extensive sample of U.S.A.

The use of real options in the valuation of investment projects, give the economic agents to evaluate flexibility or optionality that could have the project, either: to extend, postpone, amend or abandon it at a future date.

American options with binomial model: call and put

The underlying cash flows is CF_rwacc, the r_wacc is rate represented by the weighted average cost of capital, ^{Arnold, and Crack (2004)}, r_WACC, the value of exercise or delivery is K and it represents the investment in the project at any time, the deadline is T-t, the time period is δt, the underlying asset value can increase from CF to CFu or decrease from CF to CFd, with 0 < d < 1 < u and the parameters u = 1/ d, where d=e-σδt from ^{Cox et al (1979)}, and is the volatility of returns produced by the expected cash flows of the investment project, the risk free rate annualized is r %.

The expected cash flow value given market information at time t is given by E[CF | ft] = CFe^rδt, where δt is the time period considered and the risk free rate is r the annualized rate, the probability that the cash flow goes up or down in the next period is given by p=erδt-du-d the expected initial cash flow, CF, comes from future cash flows of income statement, discounted at WACC rate, and with this information is possible to construct the binomial tree of cash flow that includes their volatility. The weighted average cost of capital is given by

Where D = debt, E = equity, r = tax rate, r_E = cost of capital and r_D = cost of debt.

The present value of the American put option is given by the next equation:

With 0 ≤ i ≤ N -1 y 0 ≤ j ≤ i and in which it has a probability p to move from the node (i, j) at time iδt to the node (i + 1, j + 1) at time (i + 1)δt, and with probability 1 -p to move from node (i, j) at time iδt to the node (i + 1, j) at time (i + 1)δt.

While the present value of American call option, is given by:

So, we can to construct the binomial tree of American call option.

Merton model on assets and real options

Fisher ^{Black and Myron Scholes (1973 a}, ^b) developed a model for valuing a European option on a stock that does not pay dividends; the stock price is led by a geometric Brownian motion. However, the model was extended to non-financial assets that are not publicly traded, these are called real assets. Let CF_t the initial cash flow, K the project investment, r the rate of the risk-free rate, T-t represents the contract term, σ the volatility of returns produced by the expected cash flows of the investment project. It is assumed that the cash flows are brought to present value at WACC rate, and are guided by a stochastic differential equation at time t, and in particular, a geometric Brownian process, given by

Where µ is the average yield on cash flows. The European call option gives the holder the right to invest in the project whose expected cash flows are discounted at WACC rate, given the market information at time t, is:

Where,

The probability of expected cash flows at time T-t is:

Fuzzy model

Professor Lotfi A. ^{Zadeh (1965)} introduced the concept of fuzzy set, thus allowing for the elements of a set take different grades of membership, which can be mapped into the interval [0,1], to unlike classical theory of sets, which considers the membership of elements of a set in absolute terms, that is in the set {0,1}. The fuzzy model in discrete time is to adapt the traditional binomial model fuzzy logic; allowing operate and define the ambiguity of the underlying through triangular or trapezoidal fuzzy numbers, particularly in order to estimate movements upward or downward as it points (^{Muzzioli and Torricelli (2004)}, ^{Yoshida et al., (2006)}, ^{Zdenek (2010)}, ^{Liao and Ho (2010)}, ^{Wang (2007)}, ^{Milanesi (2014)}, and ^{Cruz-Aranda et al., (2016)}.

A fuzzy number A is a set μ_A of the real line, convex and normalized such that Ǝ x₀ ϵ R and is such that μ_A (X₀) = 1 and μ _A continuous pieces. Then all fuzzy number is characterized by a membership function, membership, μ_A: R → [0,1] and all function as described, it produces a fuzzy number, where x ϵ R, μ_A (x) is the degree of membership of for fuzzy number . The function used in the process of evaluation, It is triangular membership’ function, ^{Cruz-Aranda et al (2016)}, with the object of operating and define the ambiguity of the underlying of the option. The triangular membership function is given by

The fuzzy logic is considered in our evaluation study of the investment project of four firms in the Pharmaceutical Industry. The advantage of the fuzzy theory applied in valuation models by means of real options is that it allows the possibility of capturing a value from a lower end and growing linearly to a maximum value and decreasing linearly to the upper end of an interval, this being the base of the triangle and originating a set of possible project values. In this model according to ^{Milanesi (2014)} and ^{Liao and Ho (2010)}, values upward and downward are determined considering the volatility of returns of cash flows and its coefficient of variation cv, i.e.:

The odds upward and downward are given by:

The sum of cash flows discounted at the WACC rate is determined by:

To apply the diffuse binomial model (^{Milanesi 2014}), it requires estimation three grids (or binomial trees): The first fuzzy binomial grid corresponds to the performance of the underlying. To do this, it is considered the ratio of cash flows to present value of the project.

It is determined the reason given by RFt=CFtPVCFt whereas the underlying can be increased by the quantity u = [u₁, u₂, u₃] or decreased by the quantity d = [d₁, d₂, d₃ ] and where such magnitude is discounted from their projected fuzzy value. Therefore these cash flows are presented in the binomial tree, considering the next equation:

In the second fuzzy binomial grid projection fuzzy cash flows are calculated by incorporating the value of RF_(i,j)t,j' in each node, i.e.

The third fuzzy binomial grid is calculated from the above grids and taking into amount equivalent to the assumptions of American call option. For this reason, to build the fuzzy binomial tree of American call option (in fact a real option), with its corresponding probabilities, the value of nodes are given by

With i = 1, k = 3, m = 1, i = 2, k = 2, m = 2, i = 3, k = 1, m = 3.

To determine the positive bias, to the right, it is considered λ= AD / (AI + AD), where AD is the area of the triangle to the right of VOB _base and AI is the area of the left triangle that capturing the negative bias. The λ factor represent optimistic-pessimistic index is known by ^{Yoshida et al., (2006)}. Then the expected value, E[VOBc], of the American option with fuzzy logic, based on the defuzzification algorithm in which the expectation value is calculated by centroid method (^{Zadeth 1965}, ^{Tucha and Brem 2006}, ^{Yu, Lean et al., 2009}, ^{Cruz-Aranda et al., 2016}) we have: