Sensory Analysis of Foods

Sensory Analysis of Foods

How humans experience their food

© Copyright 2010 Umami Information Center

Olfaction

Image courtesy of www.pacsci.org/public/education/champions/ smell2.html

Olfaction Olfactory bulb

Olfactory membrane

Olfaction

X

Image courtesy of www.umds.ac.uk/physiology/jim/tasteolf.htm

Odor • Requirements for odor – Molecule must be volatile – Molecule must be adsorbed onto the olfactory hair (receptor)

Amoore Odors • • • • • • •

Ethereal Camphoraceous Musky Floral Minty Pungent Putrid

Basic Tastes (APK) • Sour -- from acids (hydrogen ion) • Salt -- metal salts (NaCl) • Sweet -- sugars, sugar alcohols, synthetics • Bitter -- alkaloids (caffeine) • Umami -- savory, meaty tastes

Tongue surface

Image courtesy of www.tcm.hut.fi/~mpaasiva/test/39/lhminen/ kopf/kieli2.html

Circumvallate papilla

Image courtesy of Anne LeMaistre (dpalm2.med.uth.tmc.edu/ edprog/00000661.htm)

Circuvallate papillae • 1 = Circumvallate papillae • 2 = Von Ebner’s glands

Taste buds • Arrow marks the taste bud

Taste buds

Image courtesy of Anne Lemaistre (dpalm2.med.uth.tmc.edu/ edprog/00000661.htm)

Taste buds

Image courtesy of Anne LeMaistre (dpalm2.med.uth.tmc.edu/ edprog/00000661.htm)

Taste buds X

Image courtesy of Tim Jacob (www.cf.ac.uk/uwcc/momed/jacob/ teaching/sensory/taste.html#Anatomy)

Taste Requirements • Molecule must be soluble in water

• Molecule must bind to taste receptor (protein)

Threshold concentrations Salt

0.02 M

Sweet

0.02 M

Sour

0.005 M

Bitter

0.002 M

Flavor potentiators • Monosodium glutamate (MSG) O

O

OH

HO

Glutamic acid

NH2

• Nucleotide monophosphates – IMP, GMP, and XMP Many of these flavor potentiators are manufactured by Ajinomoto, a Japanese company whose name means “the source of flavor”

Flavor potentiators O

H N

N

H H

O

X

N

N

O

X = H, inosine monophosphate, IMP X = NH2, guanosine monophosphate, GMP

O O O

P O-

X = OH, xanthosine monoO phosphate, XMP

Types of Sensory Tests • • • • • •

Difference tests Rank order Rating differences Descriptive analysis Threshold Affective tests Note: See pages 11-13 in your lab manual for more information about this topic.

Panel Type • • • •

Trained -- 3-10 people Semi-trained -- 8-25 people Untrained or consumer -- 100 plus Within these panels it is necessary to consider – Selection criteria (target audience) – Composition (age, sex, etc.)

Material Evaluated • Preparation – Method – Carrier (if used)

• Presentation – Coding -- random 3 digit numbers – Order of serving -- randomization – Sample size – Temperature and method of control

Presentation (cont.) – Sample container and utensils used – Time of day – Special conditions (time interval between samples, mouth rinsing, etc.)

Statistical Design • Type of experiment – Randomized block

– Factorial

Environmental Conditions • Setting (controlled sensory booth, store, State Fair, etc.) • Lighting (color)

Paired Comparison Which sample has more of a particular characteristic? 512

314

The probability of guessing the sample is 0.50.

Paired Comparison Form Judge:

Date:

Circle the sample you prefer

Pair A B C D

Sample No.

Sample No.

Paired Comparison Form Judge: Circle the sample you prefer

Pair A B C D

Date: Sample No. 555 312 498 332

Sample No. 467 778 087 714

Null hypothesis • This is the “no effect” or “no difference” hypothesis which states that there is no difference between the test and control samples • Usually referred to as Ho • The hypothesis that states that there is a difference is called the alternative hypothesis (Ha )

Level of significance • In order to determine significant differences, a level of significance is set up, usually called p, as in p < 0.05 • What this means is that there is a less than 5% probability of getting the experimental results that you got and Ho being true at the same time

Example of null hypothesis and p< 0.05 • Suppose we were doing an experiment in which we were examining the effect of steaming time on the tenderness of broccoli. The broccolis are numbered 317 (steamed 5 minutes) and 512 (steamed 10 minutes). The alternative hypothesis is: Longer steaming time produces a more tender broccoli.

Example of null hypothesis and p < 0.05

• The null hypothesis is: Steaming time has no effect on the tenderness of broccoli • If we have 20 panelists and we are doing a paired comparison we could get any number of responses if we asked them to choose the more tender broccoli

Example of null hypothesis and p< 0.05

317

512

Panel 1

10

10

Panel 2

8

12

Panel 3

6

14

Panel 4

5

15

Panel 5

4

16

Example of null hypothesis and p < 0.05 • If the null hypothesis is really true, we might expect the results from Panel 1 • But if it is not, we might get more selections of 512 than 317. How do we tell what a significant difference is? • How do we reject the null hypothesis?

Example of null hypothesis and p< 0.05

Panel 1

317

512

Ho OK?

10

10

Yes

Example of null hypothesis and p< 0.05 317

512

Ho OK?

Panel 1

10

10

Yes

Panel 2

8

12

Maybe?

Example of null hypothesis and p< 0.05 317

512

Ho OK?

Panel 1

10

10

Yes

Panel 2

8

12

Maybe?

Panel 3

6

14

?

Example of null hypothesis and p< 0.05 317

512

Ho OK?

Panel 1

10

10

Yes

Panel 2

8

12

Maybe?

Panel 3

6

14

?

Panel 4

5

15

Seems unlikely

Example of null hypothesis and p< 0.05 317

512

Ho OK?

Panel 1

10

10

Yes

Panel 2

8

12

Maybe?

Panel 3

6

14

?

Panel 4

5

15

Seems unlikely

Panel 5

4

16

Are you kidding me?

Example of null hypothesis and p < 0.05

• Set levels of significance • Set at p < 0.05 • Examine statistical table for paired comparison tests at a level of p < 0.05 and utilizing 20 panelists (Lecture notes, page 28)

Use statistical tables

Example of null hypothesis and p < 0.05

• We see that we need 15 out of 20 selections of a sample to establish that the two samples are significantly different • When we have 15 selections out of 20 we are saying that there is less than a 5% chance of having that result and have Ho be true at the same time

Example of null hypothesis and p < 0.05 • Note that if we make the statistical test more rigorous by setting p < 0.01, it takes more choices of one sample over another (16 out of 20) to establish significant differences • When we have 16 selections out of 20 we are saying that there is less than a 1% chance of having that result and have Ho be true at the same time

Duo-Trio Which of the samples is the same as the reference sample? 512

Ref.

314

Probability of guessing the right answer is 0.50.

Triangle Test

512

Find the odd sample, or find the two samples that are identical. 711

314

Probability of guessing the right answer is 0.33. Thus, this test has more statistical power than the paired comparison or duo-trio tests.

Triangle Test Form Judge:

Date

Sample No.

Duplicate Samples (indicate with an x)

546 790 243

Two of these samples are identical and the other is different. Please enter all sample numbers and check the duplicate samples in the right-hand column.

Triangle Test Form Judge:

Date

Sample No. 546

Duplicate Samples (indicate with an x) x

790 243

x

Problems with the Triangle Test Suppose the triangle test was presented as shown here.

512

311

771

1

2

3

Further imagine that even though the panelists were told that one sample was different, they were, in fact, all the same!

Middle Sample Bias

in the Triangle Test Test no. 1 and 2 1 3 2 1 3 4 4 2 5 4 6 2 16

1 and 3 5 6 4 6 4 5 30

2 and 3 2 3 2 2 2 3 14

Ranking/Rating • Structured

• Unstructured

Structured Rating

Moderately tough

Extremely tough

Slightly tough

Moderately tender

Slightly tender

Extremely tender

Note that each point on the scale has a word anchor. To use, simply make a mark where you believe the sample falls.

Unstructured Rating

No Acidity

High Acidity

Note here that only the ends of the scale are anchored. Again to use, simply make a make where you think the sample falls.

Consumer Preference • Form styles vary. • The important thing about consumer panels is that you need large numbers of panelists in order to make the statistics work out.

Hedonic Ranking – – – – – – – – –

Essentially a measure of how much the panelist __Like extremely __Like very much likes a sample. Results are X __Like moderately independent of other panelist rankings. __Like slightly __Neither like nor dislike __Dislike slightly __Dislike moderately To use, simply make a mark beside the __Dislike very much statement that you __Dislike extremely

agree with.

Texture Evaluation • Mechanical characteristics • Geometrical characteristics • Other characteristics Szczesniak, A. S. (1963) Classification of textural characteristics. J. Food Sci., 28, 385-389

Mechanical Characteristics Primary parameters

Secondary parameters

Hardness Cohesiveness Brittleness Chewiness Gumminess Viscosity Elasticity Adhesiveness

Popular terms Soft, hard Crunchy Chewy,tough Pasty,gummy Thin,viscous Plastic,elastic Sticky,gooey

Geometrical Characteristics Class

Examples

Particle size, shape

Gritty,grainy, coarse

Particle shape, orientation

Fibrous, cellular, crystalline

Other Characteristics Primary Secondary Popular parameters parameters terms Dry, moist, wet,watery Oily Fat content Oiliness Greasiness Greasy Moisture