Why an early modern, and not a classical, theriac?

The first question that confronts someone who wants to make theriac is which recipe to use. In medieval Europe the most celebrated theriac was manufactured in Montpellier, which also was the site of one of the most famous medical universities. The theriac of Montpellier contained eighty-three ingredients. Its manufacture was a serious business. The ingredients were laid out for inspection by the public, and after being found adequate, they were mixed in a public ceremony.Footnote ²⁵ But there were other competitors for the title of producers of the best theriac in Europe. During the early modern period, the theriac of Venice rose to prominence, and became the benchmark against which other theriacs were measured. Due to their city's key role in the spice trade, the apothecaries of Venice had access to recently imported, high-quality pharmaceutical simples. In Venice, too, the manufacture of theriac was subject to ritual. There too, it was a public spectacle which involved the presence of an audience as well as physicians charged with inspecting the ingredients. These practices were set in place to protect against fraud, but were also highly effective devices to market and protect the brand name of the product. Montpellier and Venice theriac were exported far and wide. Nevertheless, these cities by no means held a monopoly. There were a great number of different theriacs available in the early modern medical market and many cities and towns made the manufacture of theriac a public spectacle. It was not uncommon that the successful production of theriac was followed by the publication of a pamphlet which documented the event and the procedure used. As observed by Pugliano, short essays on theriac and its ingredients were an important genre of publication among early modern Italian apothecaries, and signalled ‘the culmination of the professionalization of the trade begun in the fifteenth century’.Footnote ²⁶

Early modern recipes for theriac were a classical inheritance, but also subject to scholarship and innovation. Di Gennaro Splendore, in an overview of early modern publications on theriac, identifies four phases in early modern understanding of theriac. The first phase, spanning 1497–1530, she characterizes as mostly scholarly, and consisted of re-publication of classical and medieval sources. This phase resulted in an early consensus among scholars that the presently produced theriacs were not ‘true’ classical theriacs, but ‘fake’ products because of their use of incorrect ingredients. The second phase, 1530–70, saw an increase in publications. Focus was still mostly on the scholarly discussion of classical texts, but during this period a small group of elite apothecaries and physicians also began to experiment with reproducing the classical theriac, hoping that it might have been an effective remedy for plague. The third and longest phase, 1570–1710, Gennaro Splendore describes as ‘the heyday of theriac’, with hundreds of writers contributing to the literature. These texts often focused on production, presenting recipes, methods of making and an extensive discussion of each of the ingredients in the composition. Many of these texts were published in vernacular languages and reached wide audiences, consisting both of professionals and of members of the public. The fourth and final period, 1710–1800, saw a continuation of widespread production of theriac, but paired with a decline in the number of publications, and increased skepticism towards the drug. As Gennaro Splendore notes, theriac's strength lay in openness, not in secrecy. Recipes and procedures were public and subject to public scrutiny.Footnote ²⁷ Theriac is indeed a very complex object. But it is nevertheless an excellent candidate for reproduction/reworking. It is unique among early modern medicaments, as there are an exceptionally large number of clear, concise instructions on how to make it, and on what ingredients to use in the composition.

The correct ascertainment of the ingredients of theriac was an important theme for early modern pharmacy, botany and philology. An important topos of this literature was that the classical ingredients of theriac were, or could be, unstable entities: prospective makers could not be sure which substances the classical descriptions signified, how they had been processed and how they should be prepared. This should not come as a surprise as theriac was indeed a reproduced medicament already during early modern times. To draw on just one example, there was an ongoing discussion on how to correctly identify the species of the balsam tree, as described in antique sources. Seventeenth- and eighteenth-century sources indicate that during that period balsam was almost impossible to obtain. Thus substitutes, such as balsam of Peru, had to be used.Footnote ²⁸ Although a kind of agreement of what constituted a true theriac andromachalis began to emerge towards the end of the sixteenth century, local variations existed. What constituted a real theriac and who could make it were, at the bottom line, decided by local authorities and hence delineated in prescribed pharmacopoeias.Footnote ²⁹ For the practically minded reworker, this means that it is not important which specific early modern recipe and manufacturing description one reproduces/reworks, if one only sticks to the chosen recipe.

The recipe and manufacturing description that we have used is from a rather unknown northern pharmacopoeia, the Pharmacopeja Holmiensis (1686).Footnote ³⁰ The Holmiensis theriac is a typical example of a seventeenth-century theriac: it is based on a classical recipe as established through Renaissance and seventeenth-century scholarship. Like almost all early modern pharmacopoeias, the Holmiensis was mainly a compilation of earlier recipes, while also showing some signs of originality. It was written/compiled by a physician, Johan Martin Ziervogel, for the Swedish Collegium Medicum, and sourced a great number of its recipes, including, apparently, with minor variations, the one for theriac andromachalis, from the Pharmacopeia Augustana.Footnote ³¹ From 1564 and onwards throughout the early modern period, the Protestant city of Augsburg produced several editions of this famous pharmacopoeia. A product of late Renaissance sentiments and endeavours, it sought to re-create the knowledge of the ancients by returning to and re-examining the original sources and pruning away such errors as had accumulated during the intervening centuries. The Augustana's editing team comprised physicians and apothecaries who were well versed in the humanist tradition, and who also took care to include knowledge garnered from the latest botanical works. Hence the Augustana – and the German pharmaceutical scene more generally – firmly connected with the lively discourse on botany and pharmacy which had its center in Renaissance Italy.Footnote ³²

We have not chosen this recipe because it was an important recipe from the point of view of early modern Europeans. The reason we have chosen it is that the Holmiensis recipe is an excellent candidate for reproduction from the point of view of substance identification. The Holmiensis remained the official Swedish pharmacopoeia into the 1770s. Hence its botanical and zoological nomenclature was used by Carl Linnaeus and his immediate circle of associates among Swedish physicians and naturalists. Hence it is easy to establish the modern names for substances mentioned in the Holmiensis, as they can be cross-checked against Linnaeus's associate Peter Jonas Bergius's Linnaean Materia medica of 1778.Footnote ³³ This means that the Holmiensis can be used as a relatively secure bridge between pre-Linnaean and post-Linnaean botanical and zoological description.

The theriac andromachalis of the Pharmacopoeja Holmiensis comprises sixty-four simple ingredient substances and two additional composite medicaments. These are agaricus trochiscatus and troches of hedychroi, which are prepared separately before they are mixed into the larger bowl containing the simple ingredients. The total number of ingredients is hence seventy-three. A list of the simple ingredients is given in Table 1 and lists of the ingredients of agaricus trochiscatus and troches of hedychroi are reproduced in Table 2.Footnote ³⁴

Table 1. Simple ingredients in theriac andromachalis according to the Pharmacopoeja Holmiensis ([Ziervogel] 1686), with modern names of substances given in Latin and English. Please note that several of the substances below were not present in the theriac given to the test panel.

Table 2. Ingredients in agaricus trochiscatus and troches of hedychroi according to the Pharmacopoeja Holmiensis ([Ziervogel] 1686).

As is apparent, theriac andromachalis contains ingredients from plant, animal and mineral realms. Not to become overwhelmed, we have chosen not to investigate growth, harvesting and transport of substances, but begin our work at the apothecary's end of the manufacturing and sales network. This means that, just like early modern apothecaries, we have had to trust the integrity of our supply chains and have relied mostly on goods that have been purchased from regular food stores and specialist suppliers.Footnote ³⁵

Parsley seeds, cloves and (Spanish) honey were purchased at the ICA Maxi food store outside Uppsala, Sweden. Deep-frozen frog's legs (Hoplobatrachus rugulosus, substituting European viper) were purchased at an Asian food store in Stockholm, Sweden. Carrot seeds were purchased at the Plantagen gardening store, Uppsala, Sweden. Clay (substituting for terra lemnia) was obtained from the soil in Näs-Söderby outside Uppsala, Sweden. Castoreum (Castor fiber) in 40 per cent ethanol was a gift from John Andersson, Uppsala, Sweden. Turpentine (Pistacia terebinthus L.) and red ochre were obtained from Kulturhantverkarna AB, Stockholm, Sweden. The recipe states wine from Spain and we used a white wine (Falanghina del Sannio bought at Systembolaget, Sweden). A total of fifty-one substances were purchased from Galke GmbH, a supplier of plant materials to the Pharmacognosy Division at Uppsala University. This brings the number of ingredients in the theriac presented to sensory assayers to a total of sixty-one. The missing twelve substances were substituted by weight using other ingredients already present in the composition.

The issue of substitutions is important and needs to be commented on. Indeed, although we later composed theriacs containing more of the ingredients called for in our original recipe, the theriac that we submitted to taste, flavour and odour assessment contains a great number of substitutes. For example, it contains neither opium nor the meat of the European viper, both considered signature ingredients of theriac andromachalis.Footnote ³⁶ Hence it would be possible to argue that we have not offered our sensory panel theriac andromachalis at all. However, substitution of the ingredients of theriac has always been a necessity and it can also be noted that precisely this type of criticism was levelled at the theriacs of the past.

Bartolomeo Maranta, author of possibly the most popular treatise on theriac of the sixteenth century, states that the physicians allowed the use of substitutions. Five or six are acceptable, but if fifteen or twenty of the ingredients are missing, then the product will no longer be theriac, but something else (res alia). When substituting, one should try to the best of one's ability to find correspondence in odour and taste and in occult and other qualities, or to use plants of similar type. Hence it is legitimate to substitute cassia with cinnamon, one root with another, and so on. One should also take into account whether they produce similar reactions when worked on in the laboratory, whether they have similar degrees of subtlety and penetration, and so on.Footnote ³⁷ Indeed, as Pugliano observes about Italy, ‘throughout the sixteenth century the race to create the perfect version of Andromachus and Galen was fought over the number of succedanea [substititions] employed: from twenty to twelve to seven, until Calzolari allegedly triumphed by using only three.’Footnote ³⁸

What Pugliano's examples show is that the use of substitutes and the research and effort needed to make decisions about what can be substituted for other ingredients are important parts of the process of making a theriac. Indeed, each and every substance that we used would be questionable, if the idea were to produce a faithful copy of a postulated original. An example is chalcitidis. Mentioned by Hippocrates, this was an iron-based medicament somewhat strangely called ‘copper-stone’ (khalkítitis). It was sourced from the run-off water of mines and probably consisted of native, copper-bearing iron vitriol which was processed into a powder. There was a corresponding product sold at early modern pharmacies, vitriolum viride. We, however, used chemically pure iron vitriol artificially manufactured with acid, which in early modern parlance would have been another product: crocus martis.Footnote ³⁹ One could argue that it would have been better to find the original product, or, failing that, to perform an analysis of water from an appropriate mine and then mix our iron vitriol with impurities. It is after all conceivable that even a small content of copper or other metallic substances in the theriac would lead to substantial differences in the final result in ways which we cannot conceive or comprehend. But remember that we are dealing with seventy-three different substances in this mixture: whatever we do, the end result will be an unknown entity, and definitely not a faithful copy of a sample produced by an early modern apothecary.Footnote ⁴⁰

Problems of this type are what led us to conclude that reworking, rather than reproducing, is a proper approach when doing practical work in historical pharmacy. There were also a couple of instances when we decided not to use the correct substance, although it was available to us. An example is our decision not to use viper (Vipera berus, the common European adder), although we received the offer to source vipers from a local Uppsala golf course, on which they were occasionally killed by lawnmowers.Footnote ⁴¹ But as the viper is a protected species according to the Berne convention, we chose to use this as a constraint on our work, as to not inspire others to use protected species for historical reproduction work. As most snakes and adders nowadays are rare, we do not wish to encourage their use for experimentation. Therefore we used frog's legs from an East Asian foodstore.Footnote ⁴² Such decisions were not consistent with the aim of reducing the number of substitutes as much as possible, but were consequences of our decision to focus on reworking, i.e. learning the process of making.

The sensory experience of making theriac

The physical preparation of theriac is not all that complicated. Once the simple substances – predominantly various dried parts of plants – are laid out in order, it is mostly a matter of hard work. It consists of the weighing, grinding, sifting, dissolving and mixing of substances over a period of a few days.

To make theriac andromachalis according to the seventeenth-century recipe in the Pharmacopoeja Holmiensis, substances of classes I to VII were ground in a stone mortar. Class VIII compounds were divided into three subclasses which were brought into solution using either turpentine or white wine. Troches of hedychroi (i.e. compacted pills) were never completed since the recipe stated that it was not necessary. Instead, the ingredients of the troches were reduced to powder in a mortar and then mixed directly into the theriac. All eight classes where then finally mixed into honey, which was kept warm at about 50 °C and, after thorough mixing, balsam of Peru and red ochre were finally added. Each ingredient in the final theriac andromachalis amounts to between 0.1 and 1.3 per cent of the final composition, whereas the ingredients in troches of hedychroi constitute between 0.02 and 0.24 per cent of the final composition. Honey, the main ingredient, makes up 75 per cent of the total weight and the other solid and liquid components make up the remaining 25 per cent. The product is a rather compact dark brown and sticky paste which produced a slight bubbling during the first weeks.

But this prosaic description of the making of theriac leaves out the most important parts of the experience. It begins when one obtains the ingredients and stacks them up in a small room full of containers of fresh and fragrant Chinese medical rhubarb, gentian root, myrrh, aloe, cubeb pepper, marjoram, saffron and other herbal drugs and spices of the early modern pharmacopoeia. Simply by entering such a room one becomes immediately aware of the powerful, sensory aspect of early modern medicine. When handled, each of these substances makes its presence known. Some odours, such as of cinnamon and saffron, are familiar and set in motion familiar trains of thoughts and associations. Others seem, at least at the outset, completely alien or just vaguely unfamiliar. But as they are handled their scents become more recognizable. They become associated with the space where they are kept, and with the practices by which they are handled.

To compose theriac means that one deepens sensory appreciation of substances. These sensory experiences were not only a rewarding part of our efforts to make early modern medicines. Handling substances also gave viable explanations to written accounts about pharmaceutical practice. This ranged from the obvious to the subtle. Among obvious conclusions is that ‘grinding work’ is not only a metaphor. Grinding is indeed heavy and boring labour. Able-bodied servants and apprentices were of course almost always at hand in early modern pharmacies, and oftentimes we, too, longed for able-bodied assistants. Among more subtle insights was that the troches of agarikon probably were an answer to work environment problems due to dust formation when grinding. These troches, or lozenges, were to be prepared in advance by grinding agarikon, mixing the powdered substance with white wine, and then forming the agarikon and wine paste into lozenges. Agarikon, when ground in a mortar, raises a great amount of irritating dust, which tends to stick to surfaces. This would be difficult to handle, and to clean up, every time agarikon is called for in a recipe. Hence it makes sense to prepare the agarikon in advance. (The lozenges do not produce dust when ground.) Similarly, we learned which substances, in particularly resins, are sticky and hence difficult to handle and retrieve when put on the scales or in the mortar. But we still have not learnt what must have been an important skill, namely the trick of how to transfer sticky resins to and from containers and scales in precise quantities without losing a small quantity of substance. This is a small problem today, as substances are rather cheap compared to other costs, such as salaries. But given the high cost of these substances during early modernity, it would probably have been considered excessive to do as we did, namely to use two spoons and rub off as much substance as possible with the other spoon repeatedly, and finally clean the residual substance sticking to them with hot water.Footnote ⁴³

It is an open question whether the use of white wine is a substitution, or simply a recognition of best and common practice. The Pharmocopoeja Holmiensis does not specify the colour of the wine, and Maranta (1576) also does not specify this. However, Maranta argues that the amount of wine should be kept down as much as possible. Hence a white wine seems to be preferrable as it makes it easy to clearly see – and hence dissolve – any remaining solid material during grinding and dissolution. The issue might seem unimportant, but it underpins our argument that the making of theriac constituted the skilful handling of qualities, and not a mechanical adding of precise quantities of substance: Maranta also states that if too much wine is used to dissolve the ingredient gums and resins, an additional amount of honey should also be added to keep the consistency right. This would indicate that a point of making theriac (at least according to Maranta) is to correctly ferment the honey, because if the mass does not ferment, the ingredient parts will not be integrated with each other. It also indicates that Maranta, author of one of the most popular treatises on theriac, does not think that the proportion of the ingredients is the most important factor behind the potency of the theriac. Rather, it is the skill of the apothecary in getting the consistency precisely right, and in not introducing too much volatile fluid (i.e. water and alcohol) that would leave the compound during fermentation.Footnote ⁴⁴

As substances are handled and become familiar, the body becomes familiar with the movements involved in doing pharmacy. We began to understand that the process of making theriac was what experimental archaeologists sometimes call a chaîne opératoire, (‘operational sequence’), bodily gestures and actions applied to materials, but also a ‘physical rendering of mental schemas learned through tradition’.Footnote ⁴⁵ It was this work that made it increasingly obvious to us why, in historical medicine making, apothecaries and other medicine makers relied heavily on input gained from their own senses and bodily experience. Our sensory and bodily experience confirmed that it made good sense to let taste, odour and visual inspection play a part both in assessments of the pharmacological potential of ingredients, and in evaluations of the medicinal effect of finished medicines. This brought us to the question of how reliable assessing through taste, flavour and odour could have been, and how reliably such experiences could be communicated among apothecaries (i.e. a gestural collective or community of practice).Footnote ⁴⁶

We also learned that theriac andromachalis, as well as many of its component ingredients, tastes and smells powerful and often wonderful. This piece of fact tends to be omitted from historical descriptions and contemporary historical studies of theriac.

The sensory assessment

Early modern patients and physicians valued the sensory characteristics of medicines. The major Greek authorities – Plato, Aristotle and Galen – all discussed the nature of odour and agreed that odours affected the human body in important ways, and Aristotle noted that some odours had corresponding flavours. Medieval authors elaborated these theories connecting odours to bodily health. Odours were conceived as having material effects; as vapours they worked directly on the pneuma or the spirit of the human body and had a particularly powerful effect on the brain. Odours could, of course, be either beneficial or detrimental to health.Footnote ⁴⁷

Simultaneously, sensory information is notoriously difficult to transmit textually and today we know very little about the sensory characteristics of historic composite medicines. Given the importance attached to sensory evaluation by medical practitioners – from antiquity and well into the nineteenth century – this is a problematic lacuna in our knowledge of how historic actors perceived and used medicines. This part of our study approaches this problem by seeking to answer the question of how theriac can be construed as an object through linguistic description of its sensory qualities.Footnote ⁴⁸

We do this with recourse to modern methods of taste, flavour and odour assessment. There are many important reasons underlying this choice. First, the protocols used in food science aim to transfer sensory experience into standardized graphs and descriptions. This provides a means to transfer sensory impressions to the medium of print. Second, we use a modern protocol for safety reasons. Putting physiologically active substances, i.e. historically used medicines, in the mouths of people (such as students) is not something that historians should just start doing. There are many potential dangers, not just concerned with potential toxicity issues. Many of the substances used in historical pharmacy are, in the present day and age, rare or completely disused as medicines or foodstuffs, and test persons may not be expected to have come across them before trials. This means that it is a good idea to reduce exposure to a minimum in order to reduce the risk of harmful effects, such as allergic reactions. It is also absolutely necessary to have access to competence in pharmaceutical science as well as such protocols as have been developed in food science for the safe administration of foodstuffs. Experiments of this type are in fact experiments on human subjects. This implies that ethical rules must be followed. Safety considerations also present us with a further problem, from the authenticity point of view. Historically, theriac was usually taken in small quantities, either straight out of its container, or rolled into pills.Footnote ⁴⁹ In order to reduce exposure, the theriac presented to the taste panel was dissolved in alcohol and strained before being assessed.

Solutions were made through extraction of the theriac using 40 per cent weight/volume ethanol (Absolut Vodka, Åhus, Sweden) to a content of 4 per cent w/v, in brown flasks with a glass stopper. Extraction commenced for one week at a temperature of approximately +10 °C and the flask was shaken every day for a few seconds. After filtration through a coffee paper filter the samples were prepared according to the following:

• Odour samples for sensory analysis were prepared at 4 per cent (w/v) content. The samples were prepared by soaking a cotton pad with about five millilitres of test solution into an aluminium box (fifteen millilitres in volume) equipped with an aluminium screw-on lid.

• Oral samples (taste and flavour) were prepared at 0.5 per cent (w/v) content and about five millilitres were taken into ten-millilitre brown glass flasks with aluminium stoppers.

Test samples were prepared at the Pharmacognosy Division, Department of Medicinal Chemistry, Uppsala University, Sweden, and transported by train to Kristianstad, Sweden, where sensory analysis was performed at the Department of Food and Meal Science, Faculty of Science, Kristianstad University. Test samples were stored in a refrigerator (+4 °C) upon arrival and accommodated to room temperature for one hour before sensory analysis. Reference samples were prepared in beakers with lids to help the sensory panel identify tastes and odours in the samples. The reference samples were: fresh lemon, fresh lemon peel, fresh ginger (minced), eucalyptus pastilles for managing cold (Vicks® Blue, extra strong, Procter and Gamble, USA), dry juniper berries (Kockens kryddor, Lyckeby Culinar, Sweden), fresh mint leaves, fresh grapefruit, fresh lime, clove and allspice (Kockens kryddor, Lyckeby Culinar, Sweden), Swedish Christmas non-alcoholic carbonated drink (Julmust, Apotekarnes, Sweden) and honey (Svensk Biodlarförening, Sweden) diluted in warm water. In addition to assessing theriac, the panel also assessed six simple substances on the same occasion. These were agarikon, zedoary, aloe ferox, saffron, myrrh and Chinese rhubarb root.Footnote ⁵⁰

The samples were analysed by a slightly modified version of the Flavour Profile Method® invented by Arthurs D. Little.Footnote ⁵¹ The modification consisted of the use of a scale running from zero to 100 instead of the shorter scale used in the original method. The sensory panel consisted of eight assessors who were selected and trained according to ISO Standard 8586-2:2008, meaning that they were selected due to having highly sensitive senses of taste and olfaction.Footnote ⁵² Before assessing the samples, they rehearsed how to perform testing and how to judge intensity on a numerical intensity scale, running from zero to 100. References and a few selected odour test sample extracts were assessed until consensus was reached before the main assessing of the ingredients took place.

The assessors were instructed to identify and describe the sensory attributes, taste, flavour and odour, in each test sample until consensus was reached upon a definition for each attribute. Then each attribute was assessed using the intensity scale. The assessors were instructed to use the full length of the scale to distinguish between samples which only slightly differed from each other. Each assessor needed to agree upon the placement of each attribute along the intensity axis. Between each sample the sensory panel had a break for ten minutes to refresh their senses. The assessors were instructed to use water and neutral wafers to clean their palate and neutralize their senses. The assessors were informed not to swallow the samples and to spit out right after assessment. Further, before agreeing to join the assessments, the panelists were informed about the samples and their potential as pharmaceutical ingredients using information from a standard textbook in pharmacognosy.Footnote ⁵³

Following the rules for informed consent, each assessor signed for participation after being informed about the products and the terms of participation, which meant voluntary participation, freedom to leave the test without giving a reason, the right to decline to answer specific questions and an assurance that their participation would not affect their future treatment in the healthcare system in any way.